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aircraft:tmd:propulsion [2017/01/23 21:34] jhaircraft:tmd:propulsion [2021/02/12 12:31] (current) – [Propeller Propulsion] jh
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 ===== Propeller Propulsion ===== ===== Propeller Propulsion =====
  
-A propeller in the Aerofly FS 2 is usually connected to a [[rigidbody]] object. That ''Body'' is then rotated around a [[jointmulti]] by a drive shaft [[jointtorque|torque connection]]. So in short: the engine acts a torque upon the driveshaft which turns the propeller that then creates thrust based on its rotation speed, pitch and airfoil.+[[propeller]] in the Aerofly FS 2 is usually connected to a [[rigidbody]] object. That ''Body'' is then rotated around a [[jointmulti]] by a drive shaft [[jointtorque|torque connection]]. So in short: the engine acts a torque upon the driveshaft which turns the propeller that then creates thrust based on its rotation speed, pitch and [[airfoil]].
  
 In the Aerofly FS 2 there are a couple of engines to choose from: In the Aerofly FS 2 there are a couple of engines to choose from:
-  * [[engine|combustion engine]] +  * Turboshaft engines made from [[aircraft:tmd:turbo_engines|turbo engine components]] 
-  * [[electric_engine|electric engine]] +  * [[engine|Combustion engine]] 
-  * [[turboshaft|turboshaft engines]]+  * [[electric_engine|Electric engine]]
  
 +See the guide to [[aircraft:tmd:turbo_engines|turbo engine components]] for more detail.
 ===== Jet-Stream-Engines ===== ===== Jet-Stream-Engines =====
  
 Jet stream engines compress air, mix it with fuel, burn it in a combustion chamber and accelerate the hot gases through turbine blades. There are numerous ways to create such an engine and each has their own characteristics. In the Aerofly FS 2 the following jet stream engines are implemented: Jet stream engines compress air, mix it with fuel, burn it in a combustion chamber and accelerate the hot gases through turbine blades. There are numerous ways to create such an engine and each has their own characteristics. In the Aerofly FS 2 the following jet stream engines are implemented:
  
-  * turbofan (high by-pass-ratio engine used for airliners like the A320, B747+  * [[aircraft:tmd:turbo_engines|modular turbo engines]] for high by-pass-ratio turbofan engines used for airliners like the A320, B747 and low by-pass-ratio engine for jet trainers like the MB339 alike. 
-  * turbojet (low by-pass-ratio engine for jet trainers like the MB339) +  * [[turbofan]], [[turbojet]] legacy engines with simplified simulation (usage will be faded out over time). 
-  * jet_engine (afterburning turbojet engine used in flighter jets like the F15E or F18)+  * [[jet_engine]] afterburning turbojet engine used in fighter jets like the F15E or F18.
  
-The implementation of these engines in the Aerofly simulator follows the international standard nomenclature for jet stream engines. It assigns numbers to the different locations within an engine+See our guide to [[aircraft:tmd:turbo_engines|modular turbo engines]] for more detail. 
 +===== Rocket Engine =====
  
-All air from the outside, far in front of an engine (0) enters through the intake (1) and is split into the core (1) and bypass air flow (12). The bypass air masses are accelerated by the fan or "booster" (13) and exit the engine directly (19). +Rocket Engines are currently only partly implemented. The ''rocketengine'' class is still recognized but currently broken (as of today, 23rd of Jan2017). It might be re-added laterplease contact us if you need this type of propulsion for your projectHere is a pretty image of a Laval nozzle in the mean time :D 
- +{{ :aircraft:tmd:rocketengine.png?nolink |}}
-The core air masses are further compressed (21 to 3). They enter the combustion chamber at a relatively slow airspeed (3)where they hit the hot flames. The exhaust is accelerated from the end of the combustion chamber (4) towards the lower pressure rear end of the engine (5)The turbine blades (4 to 5) that spin in the airflow that is rushing towards the low pressure end hereby extract the heat energy in the air flow and converted it into mechanical power to drive all other components (compressor and fan) via shaft in the center of the engine. +
- +
-The afterburning turbojet engines take the still hot exhaust gases and mix it with fuel for second time (at 5, between 5 and 7). The resulting fuel burn is not as efficient but it increases the maximum thrust further for short term applications. +
- +
-All exhaust gases then finally leave the engine through the nozzle (7 to 9) which is can be mechanically controlled in afterburning fighter jet engines. +
- +
-{{ :aircraft:tmd:intl_standard_nomenclature_jetengine.png?nolink |}}+
  
  
aircraft/tmd/propulsion.1485203650.txt.gz · Last modified: 2017/01/23 21:34 by jh