I have no clue as to what is outdated, perhaps you could give a detailed response to which I {or any other mod) can act upon and update as you've requested.
TTZA - 400hpI have no clue as to what is outdated, perhaps you could give a detailed response to which I {or any other mod) can act upon and update as you've requested.
Despite CAATSA your collaboration not only with GE but with other American companies is still going on, what else do u need.So GE pockets %46 of the TEI's profits but doesn't help with CAATSA and other US senate secret embargos? What a great partner.
What do commercial products have to do with CAATSA? If the bilateral trade volume with America is not as it should be, who can guarantee that the merchant ships will not pass through the straits with a delay of 3 months?Despite CAATSA your collaboration not only with GE but with other American companies is still going on, what else do u need.
What does he mean @Cabatli_TR @Yasar @Nilgiri @Merzifonlu and others?We really need a variable cycle engine for MMU if we want to compete with European programs.
The road to the top of the mountain passes through the slopes of the mountain. Let's first design and manufacture the "ordinary" 5th generation engine that can produce 35.000 lb thrust.
A turbojet engine is most efficient in higher altitudes where air is rarified. All the air sucked in through the fans in to the compression section, after helping burn the fuel in combustion chamber, is exhausted from the nozzle creating jet thrust. 100% of the thrust is generated by the air going through the engine.
Also heard Tubitak is trying to develop a submarine diesel engine but the details are unclear.
Lobbying in our favour.Despite CAATSA your collaboration not only with GE but with other American companies is still going on, what else do u need.
Lobbying in our favour.
His implying ~1:1 bypass ratio for TF-6000 illustrates the MIUS basically will balance supersonic capability with payload/range/endurance curves as best as theoretically possible. Since going above this will make supersonic impossible and going well below it (and having lower bypass realm) will reduce the mass and payload efficiency of the platform.
Military turbofans that go supersonic also have to follow this constraint and are essentially fan augmented turbojets. There is more design expectation for such aircraft to perform in the subsonic realm (compared to say a concorde) so having/balancing as much as bypass as possible is a good advantage since you have more effective range/time that way.
But generally cannot go much above a bypass ratio of 1:1 if you want to have supersonic capability (you start to invest too much in the fan side of things and impose penalties on the core relative to the mission/design profile of the aircraft). i.e To better provide for supersonic capability at larger engine thrusts, simply the bypass ratio is often kept in 0.5 - 0.8 design range so as to not impose on having larger afterburner or having complex intake systems for the engine itself.
SFC is most directly correlated to bypass ratio (which is also correlated to engine diameter by way of needing larger fan as you grow it).
Bypass ratio is by far the largest factor in increasing thrust of a jet engine efficiently since you are "gearing" air to move in larger volume at slower speed rather than vice versa (i.e smaller volume at higher speeds ....which uses far more energy to do, but is only option to increase thrust when you have zero bypass like in a turbojet, which is why turbojets have higher SFCs in comparison generally).
However if you want the engine to go supersonic (and have some range of supersonic past just mach 1), the bypass ratio can only be increased to a point as the effective jet exit velocity has to also be that supersonic velocity (and fans cannot produce supersonic air, as it is detrimental to have their blade tip speeds operate past supersonic which is a longer conversation to get into).
This is exactly why the concorde used turbojets (with no bypass) for example....as there was little to no design expectation for the aircraft to perform in subsonic role and harness any efficiency from that range of speed where a fan would be useful.
Military turbofans that go supersonic also have to follow this constraint and are essentially fan augmented turbojets. There is more design expectation for such aircraft to perform in the subsonic realm (compared to say a concorde) so having/balancing as much as bypass as possible is a good advantage since you have more effective range/time that way.
But generally cannot go much above a bypass ratio of 1:1 if you want to have supersonic capability (you start to invest too much in the fan side of things and impose penalties on the core relative to the mission/design profile of the aircraft). i.e To better provide for supersonic capability at larger engine thrusts, simply the bypass ratio is often kept in 0.5 - 0.8 design range so as to not impose on having larger afterburner or having complex intake systems for the engine itself.
To answer your query at the end, this generally results in military turbofans (be it for trainer size or TF-X size) being bounded to SFC of 0.6 - 1.0 , and that will be where Turkiye's future military turbofans (i.e those that intend to have supersonic capability) will also generally be....depending on their respective design profile balance.
Pushing below 0.6 (i.e growing the bypass ratio more) comes with consequences where the engine (given its resulting size and thrust) becomes more akin to one used for a supersonic bomber rather than a fighter etc when it comes to military use..... or for civilian use the first range of turbofans that can be used in business jets and generally smaller civil aircraft.
Pushing it even lower (than say 0.5, 0.4, 0.3 etc) needs drastically larger bypass ratios and you enter the realm of (fully subsonic) cargo aircraft and civilian aircraft.
Turbofan concept naturally orients (its growth by larger and larger bypass ratio and fan diameter) to subsonic use and using the larger thrust to simply propel larger aircraft (rather than using thrust to propel faster supersonic aircraft where you need to make the turbojet design/aspect better).
Turbojet concept naturally orients itself to supersonic use in comparison.... hence we have essentially a hybrid of the two concepts in (supersonic capable) military turbofans.