Doublers, usually but not exclusively ply, serve 2 purposes; they strengthen the construction around high stress areas and also transfer the extra energy to other parts of the airframe.
Firstly a bit of theory, but if you only ever build from kits or plans and never think about “tweaking” the construction then feel free to skip the next 3 paragraphs! Personally though I think an understanding of why we do the things we do the way we do them never goes amiss.
The first thing to grasp is the fact that energy can neither be created nor destroyed; we can only change its’ form, there is the same amount of energy in the universe today as on the day of creation. For example, when we open the throttle the energy stored in the fuel is converted by the engine / prop into Kinetic Energy (mass and speed) and Potential Energy (mass and altitude). Not all the output from the engine is converted usefully, there are some “loses” caused by friction (drag), this produces heat energy, not a lot in our case but just think of the Space Shuttle re-entry and sound energy, that lovely whistle especially with all the rigging used on biplanes.
A simple “box” fuselage is very strong but we have to have access to the radio gear etc. through a hatch or the wing seat and this produces a weak spot. Doublers are used to strengthen the fuselage sides and transfer energy from the firewall and often the undercarriage mounting across this weak spot to the rear fuselage. When designing doublers avoid ending with a single vertical joint, this will concentrate the energy at this point, try to spread the energy over as large an area as is practical.
In the example shown below there was no plan supplied with the kit so a paper template is traced around the fuselage and the internal structures drawn on, the proposed doubler is outlined in red. In the case of a heavy landing the energy is concentrated at the undercarriage mount just in front of the wing seat, the doubler greatly increases the strength of the balsa fuselage sides and the energy is carried over the weak wing seat area, when it gets to the fish tail (nice description Dave!) it is divided so half goes to the top longeron and half to the bottom.
When gluing ply doublers it is important to sand the faces of the ply. The manufacturers use a release agent on the presses which by its’ very nature is designed not to stick; the amount of release agent left on the ply varies greatly but generally the thinner the ply the more there is. “Contact” adhesive is often recommended but personally I don’t like it, if the fuselage has rounded corners and you sand down to the doubler the glue pulls out and generally makes a nuisance of itself. I use PVA, the only problem being that the sides have to be held flat overnight whilst the glue dries, just make it last job of the evening and put them under your building board.
[ATTACH]7297.IPB[/ATTACH]
[IMG]/monthly_2004_12/doubler.jpg.99249754f299ced00dba70af491965f0.jpg[/IMG]
[ATTACH]11992.IPB[/ATTACH]
[ATTACH]12592.IPB[/ATTACH]
Firstly a bit of theory, but if you only ever build from kits or plans and never think about “tweaking” the construction then feel free to skip the next 3 paragraphs! Personally though I think an understanding of why we do the things we do the way we do them never goes amiss.
The first thing to grasp is the fact that energy can neither be created nor destroyed; we can only change its’ form, there is the same amount of energy in the universe today as on the day of creation. For example, when we open the throttle the energy stored in the fuel is converted by the engine / prop into Kinetic Energy (mass and speed) and Potential Energy (mass and altitude). Not all the output from the engine is converted usefully, there are some “loses” caused by friction (drag), this produces heat energy, not a lot in our case but just think of the Space Shuttle re-entry and sound energy, that lovely whistle especially with all the rigging used on biplanes.
A simple “box” fuselage is very strong but we have to have access to the radio gear etc. through a hatch or the wing seat and this produces a weak spot. Doublers are used to strengthen the fuselage sides and transfer energy from the firewall and often the undercarriage mounting across this weak spot to the rear fuselage. When designing doublers avoid ending with a single vertical joint, this will concentrate the energy at this point, try to spread the energy over as large an area as is practical.
In the example shown below there was no plan supplied with the kit so a paper template is traced around the fuselage and the internal structures drawn on, the proposed doubler is outlined in red. In the case of a heavy landing the energy is concentrated at the undercarriage mount just in front of the wing seat, the doubler greatly increases the strength of the balsa fuselage sides and the energy is carried over the weak wing seat area, when it gets to the fish tail (nice description Dave!) it is divided so half goes to the top longeron and half to the bottom.
When gluing ply doublers it is important to sand the faces of the ply. The manufacturers use a release agent on the presses which by its’ very nature is designed not to stick; the amount of release agent left on the ply varies greatly but generally the thinner the ply the more there is. “Contact” adhesive is often recommended but personally I don’t like it, if the fuselage has rounded corners and you sand down to the doubler the glue pulls out and generally makes a nuisance of itself. I use PVA, the only problem being that the sides have to be held flat overnight whilst the glue dries, just make it last job of the evening and put them under your building board.
[ATTACH]7297.IPB[/ATTACH]
[IMG]/monthly_2004_12/doubler.jpg.99249754f299ced00dba70af491965f0.jpg[/IMG]
[ATTACH]11992.IPB[/ATTACH]
[ATTACH]12592.IPB[/ATTACH]
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