Many aircraft have a semi active system. Well I guess you can call it that. The outer tips of the blades are made of an abradable material that as the blades heat up and expand wears down bit by bit. This ensures that at the correct operating temperature limits the blades are still within spec clearance wise from the housing.wuzak wrote:No. It has to be fixed geometry.Brian Coat wrote:Is active clearance control permitted within the rules?
Bit of read but provides some useful information: http://www.google.com/patents/US5704759gruntguru wrote:Interesting. I wonder if that has ever been done on radial inflow turbines. The region of critical clearance for a radial inflow turbine is the curved section of the impeller rather than the very tip.
When you say casing what do you mean exactly? The combustion chamber? Or the casing around the combustion chamber that is used to carry cooling and combustion dilution air flow? Or something else?Brian Coat wrote:Aero engines also control clearances actively by modulating airflow to the casing.
This is to allow for the fact that the engine is not so hot in cruise as in climb, so the clearances go up.
Is variable cooling fixed geometry?
Well the thing is before the abradable liners were introduced, compressor blades had a much shorter lifespan. Now many aviation engine components have a much higher limit with a "on condition" maintainence program tacked on which can allow, in special cases' to allow the engine to go passed overhaul times. Before because there were no liners after very little blade creep the compressor blades would have to be changed. Very costly and time consuming considering all the blades have to be dynamically balanced as a set. Also as engines have got larger, so have compressors, diameter wise included. This obviously means more growth over time.Brian Coat wrote:Apologies trinidefender I was talking about two different parts of the engine in the two posts and I did not make it clear.
Abradable liners of the type described in the patent above are used in the *compressor* and are different to those in the turbine.
"A few mm" of high temperature creep growth in compressor blades is puzzling me ...
Where the temperatures are higher at the back end of the compressor there is very often no liner. And some engines don't use abradable liners at all in the compressor. The creep growth you describe would be a disaster in such cases?
For clearance control I was referring to the *turbine* and I mean the turbine casing not the combustion casing, the geometry of which cannot be used to control clearances, of course. Here is a brief description of the method.
http://en.m.wikipedia.org/wiki/Active_t ... ce_control
Clearly a few percent of MGU-H efficiently would be very worth realising and there probably lots of things to try, even if the geometry is not allowed to be variable.
Question then. What is the time that is spent at full throttle on the longest track per lap?Brian Coat wrote:In RET this month Rob White was asked if MGU-H power is about 90kW: "You are in the ball park and have the right number of zeroes" or words to that effect.
Gnomic as usual but implies < 100 kW?
Probably no shock given you'd only need 120 kW in order to run round at full load with no braking!
Can you give me a time figure for full throttle for the whole lap?godlameroso wrote:Spa has 22 seconds of full throttle from La Source to Les Combes, I think that's the longest full throttle stretch.
