Gas turbine rpms - sea level & cruise?
Can anyone tell me for a given throttle setting how the rpm of the different stages in a turbofan vary between sea level (airport height will do) and cruise (say 35,000ft)?
It would seem reasonable that as the air is thinner at altitude that the fan could turn faster. Is this the case, and what about the other stage or stages in the engine? |
Originally Posted by Mechta
It would seem reasonable that as the air is thinner at altitude that the fan could turn faster.
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Mechta
HN39's response is correct. On most two spool engines, fan speed (N1) is controlled setting the power (thrust) to achieve desired speed at any altitude. Thrust is more accurately controlled because all the air passes through the fan with only a portion passing into the core. For various reasons, core speed is not an optimum manipulated variable to control fan speed. However, in three spool engines, the control for thrust seems to be N2, or the speed of the IP spool. Either way, since the spools are coupled, the speed of the fan remains within the desired power/thrust settings. |
HazelNuts39 and Turbine D, Thanks for the replies. As I understand it, from what you are saying, the three stages stay at pretty much the same ratio of RPMs to each other, but I'm still not sure whether the RPM of N1 changes significantly with altitude, all other things being equal?
since posting the original question, I've since found this thread: http://www.pprune.org/tech-log/31248...rb211-rpm.html This suggests that air density makes a difference to rpm, I'm curious by how much though. Does the fan (and the rest of the engine in proportion) not unload and increase rpm when at cruise altitude and speed to a significantly higher level compared to when the aircraft is static and near sea level? |
Spool speeds, etc.
Mechta;
Sorry, but you have to explain more specifically what question you have. Your OP question was about rpm variation "for a given throttle setting", and Turbine D and I replied to that question. If you are asking about rpm's for the maximum thrust available within a given thrust rating (e.g. Max CLB), that's another story. If you are talking about rpm's for the same thrust (e.g. EPR) at various temperatures at a given altitude, that's yet another story. regards,HN39 P.S. For a given thrust, altitude and Mach, rpm's of all spools vary in direct proportion to square root of ambient temperature (absolute, e.g. Kelvin). For given ambient temperature, rpm and Mach, thrust varies proportional to ambient pressure. |
When did fuel-control systems change from mechanical to partially-electronic, to full-electronic?
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This thread is very interesting.
I'm often having a question for the factor that effect the compressor speed vs altitude. Is it possible that : -the higher it go, the lower temp it is, and hence the more EGT margin that the engine could archive with out burning the turbine. [I'm heard some old engine like JT8D use the EGT as the factor to determine the maximum thrust output] -The higher we go, the more ram air pressure [for a typical flight], and hence the compressor can produce more pressure to turn the turbine and hence higher compressor speed. - Or the Fuel Control Unit always work to keep the Compressor ratio constant? Best Regards |
Jane-DoH;
Don't remember. I suggest you go to Wikipedia and search for "FADEC". regards, HN39 |
Originally Posted by Mr.Vortex
I'm heard some old engine like JT8D use the EGT as the factor to determine the maximum thrust output
-The higher we go, the more ram air pressure [for a typical flight], and hence the compressor can produce more pressure to turn the turbine Or the Fuel Control Unit always work to keep the Compressor ratio constant? regards, HN39 |
-the higher it go, the lower temp it is, and hence the more EGT margin that the engine could archive with out burning the turbine. How wrong am I? :O Best regards Escape Path |
-the higher it go, the lower temp it is, and hence the more EGT margin that the engine could archive with out burning the turbine. regards, HN39 P.S. By "EGT margin" I understand you mean the difference between the limiting EGT and that corresponding to the thrust rating. As said earlier, the rating selection is somewhat arbitrary. There is no particular reason for the 'margin' to increase with altitude, on the contrary perhaps. |
I am confused. Has someone really answered the OPs post?
I am curious to know the answer to his question, whether the RPM of the fan stays the same or increases for a given power setting as you go up in altitude. I will ask some questions to try to clarify this matter. Let's say you use N1 (fan rpm) as reference. N1 will be shown as a percentage of the fan maximum RPM. If I set a certain N1 setting for take off and do not move the thrust levers as I climb, what will the N1 display show (assuming no autothrottle etc.)? If I am not mistaken it will decrease as we go up in altitude, meaning that the fan RPM will goes down, which means that we have to move the thrust levers forward to keep our maximum fan speed or N1 setting. However, when we reach that same N1 value (if throttle lever movement is sufficient to do so), since we are higher up, the engine will not be able to produce the same amount of thrust due to the thinner air. So does that not mean that to maintain a certain power setting at higher altitude, RPM will have to go up? And also, if we are able to keep the same amount of thrust from the ground and up, RPM will have to increase? I am no expert on this so please correct me if I am wrong. |
minimumunstick;
N1 will be shown as a percentage of the fan maximum RPM. If I set a certain N1 setting for take off and do not move the thrust levers as I climb, what will the N1 display show (assuming no autothrottle etc.)? If I am not mistaken it will decrease as we go up in altitude, meaning that the fan RPM will goes down), which means that we have to move the thrust levers forward to keep our maximum fan speed or N1 setting. the engine will not be able to produce the same amount of thrust due to the thinner air. regards, HN39 P.S. Density depends on pressure and temperature. It is usual to treat these parameters separately, since they have distinctly different effects on engine performance, as explained in earlier posts. |
Thanks for your post HazelNuts39
If I set a certain N1 setting for take off and do not move the thrust levers as I climb, what will the N1 display show (assuming no autothrottle etc.)? I know some things can't be oversimplified, but yet.. Also I might have worded myself poorly. When I said "set a certain N1 setting" I didn't mean set the N1 as a permanent setting or in a computer or whatever, I meant move the throttle levers so that we have a specific N1 power setting at sea level on take off (again disregarding any FMS etc to control performance on T/O or climb or whatever) Let me try again to make myself more clear: We are on the runway and move the thrust levers 3/4 forward. We take off and climb and do not move the thrust levers from their position. Will the N1 that we had on the take-off roll at sea level increase or decrease? As I said in my previous post, if I understand correctly the N1 percentage displayed will decrease, correct? So for a given throttle lever setting RPM will decrease with altitude, which means that we need to move the throttle levers forward to keep the same N1 setting as we climb. If we again disregard any FMS or FADEC etc., this will mean that as we climb, engine performance will deteriorate due to higher density altitude / lower density? Does this not always apply? (you wrote see previous posts, but I couldn't really find an answer to this, probably because some of the replies given might have been a little too complicated for me to understand, so if you care to point me in the right direction on this I would appreciate it) P.S. Density depends on pressure and temperature. It is usual to separate these parameters, since they have distinctly different effects on engine performance, as explained in earlier posts. Thanks |
If the pilot sets an RPM on any jet engine the function of the fuel control unit is to maintain that RPM regardless of any change in airspeed or altitude UNLESS changes are needed to keep the engine inside any of its operating limits.
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If the pilot sets an RPM on any jet engine the function of the fuel control unit is to maintain that RPM regardless of any change in airspeed or altitude UNLESS changes are needed to keep the engine inside any of its operating limits. |
Electronic controls - when?
So-called PMC's (Power Management Controls) - electronic controls performing fine trim on a basic hydromechanical system - came into the commercial engine market about 1982. The first I recall were on the CF6-80A on 767s and A310s.
FADEC - Full Authority Digital Electronics - were a few years later, mid or late 80s |
Originally Posted by minimumunstick
the basics of how engine thrust and fan speed is affected by increased density altitude in a pure aerodynamic sense, disregarding any autothrottle or FADEC systems or specific technicalities.
Originally Posted by me
P.S. For a given thrust, altitude and Mach, rpm's of all spools vary in direct proportion to square root of ambient temperature (absolute, e.g. Kelvin). For given ambient temperature, rpm and Mach, thrust varies proportional to ambient pressure.
as we climb, engine performance will deteriorate due to higher density altitude / lower density? Perhaps I should stop here and await further questions, rather than repeating what I wrote earlier. regards, HN39 |
Not sure I understand or want to understand some of the replies in this thread, but I have absolute data for the A320 in front of me, and the reality is that for a given N1 RPM% value the thrust produced by the engine will change with altitude....
See here: N1% = 78%, FL50, thrust = 29387N, CAS = 259kts N1% = 78.2% FL370, thrust = 14130N, CAS = 260kts/M0.802 Therefore, it is my understanding that the FADEC (or whatever control system is in place) adjusts the fuel delivery to maintain the demanded RPM, with thrust changing as a function of altitude. This makes sense since at lower altitude the air is 'thicker' and hence you need more push to achieve a given forward speed, with the air density decreasing the higher you get, hence you need less push... The point is that 78% N1 RPM is always the same irrespective of altitude (i.e. the blade passing frequency will be maintained), what varies is the fuel burn needed to maintain this RPM, as a consequence the thrust delivered by the engine. - GY |
Garageyears
The point is that 78% N1 RPM is always the same irrespective of altitude and just what is or how is 100% defined. Unless the definitions are defined it might turn out that even the 100% number varies with altitude. |
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