Turbofan:Compressor

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Revision as of 19:55, 28 February 2011 by Vincent (talk | contribs) (Adding compressor pictures)
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Compressor design

Real-world engines can have nearly 20 compression stages. We will first build a 3-stage compressor, in a single-spool engine to assess how it can be scaled to a full power engine, or if it will require more stages (= quite costly). Blade design and manufacturing have a dedicated page. The two pictures below show an overall sketching of the compressor with all its blades.

Rotor design

Special care has to be given to the rotor, since it will spin at very high rotation speeds (not calculated yet).

A blade mounting failure will likely cause the loss of the aircraft, given the constraints. The part that holds the blades is called the hub. We'll call the part of the blades that is hold by the blades at their root the insert.

Fan and compressor's fisrt stage blades mounting

For the first compressor stage and the fan, blades are long enough to have a root parallel to the shaft. An innovative design for the hub would be to a use spacer part between each blade. The whole compressor stage fixation would be the result of all blades and spacer put together side by side. It would be like a pie chart, in which separations are the blades' inserts. This design is probably not used on real planes for two reasons: it's more heavy, since the inside of the compressor stage/shaft is full of metal, and it's too complicated for higher stages as we will see below. This design is depicted below.

PICTURE NEEDED

An alternative design would be to have the blades moving freely from the hub, and when assembled, a key of some sort would fix them on the hub. The hub and the blades would have a notch in the same place, in which a ring-shaped key would place to hold everything together. This keyed design is also considered for higher stages, and is illustrated in the models below.

2nd and 3rd stage's compressor blade close-up and manufacturing

Higher stages have shorter blades, and need to have the base of the blade non-parallel to the shaft for their twisting to be acceptable. That brings problems to the design and manufacturing of the blade insert and the hub: creating a part that can be duplicated to form a cylinder, but with a non-parallel-to-the-axis separation.

We propose a more usual solution to this problem, based on a real standalone hub in which are milled the inserts holes. Blades' inserts would remain a linear part and the milling of the hub would thus be linear too. Since it's a round part, this makes a strange effect, but allows the blades to be properly and easily fixed. A keyed design could also be added on the extremities of the blades, i.e. the side of the hub. The pictures below represent this mounting system, in exploded view (larger versions available). The hub is the grey round part with only one insert milled in it, the yellow part is the inter-stage spacer that has the key holding the blades.

Below is a close-up on the blades mounted on the hub (in orange) and on the key system from the inter-stage spacer (in yellow).

Stator design

The stator will have as main issue the fact that blades must have a very thin insert. Shaping them like a T should be considered.