i dont know why the hell cobra has only 2 roter blades where basic physics tells that more the blades,more the lift ,less the noise(my theory),may be super cobra has 4roter blades?.
Nope, only increasing the number of blades do not increase lift or reduce he noise. Many factors, including wing design, dimensions, rpm etc decide the overall performance. You can achieve better results with two blades compared to four or more, by enhancing other parameters.
Increasing the numbler of rotor blades
DO increase lift but could be cancelled out by not increasing the performance levels of other factors such as rpm or blade shaping.
Blades and Dissymetry of lift
The weight of a helicopter is divided evenly between the rotor blades on the main rotor system. If the helicopter weighs 5000 lbs and it has two blades, then each blade must be able to support 2500 lbs and so on. The more blades a helicopter has then the lower the weight that is carried on each blade compared to the same helicopter with less blades.
In order to understand why the two-blade configuration is so popular one must delve into the history of the helicopter itself. The above link has this paragraph...
All rotor systems are subject to Dissymetry of lift in forward flight. At a hover, the lift is equal across the entire rotor disk. As the helicopter gains airspeed, the advancing blade develops greater lift because of the increased airspeed (for example, if your blades at a hover move at 300 knots and you fly forward at 100 knots, your advancing blade is now moving at a relative speed of 400 knots and your retreating blade is moving at 200). This has to be compensated for in some way, or the helicopter would corkscrew through the air doing faster and faster snap rolls as airspeed increased.
Dissymetry of lift is compensated for by BLADE FLAPPING . Because of the increased airspeed (and corresponding lift increase) on the advancing blade, it flaps upward. Decreasing speed and lift on the retreating blade causes it to flap downward. This INDUCED FLOW through the rotors system changes the angle of attack on the blades and causes the upward-flapping advancing blade to produce less lift, and the downward-flapping retreating blade to produce a corresponding lift increase. Kinda spooky, huh? Anyway, it all balances out and the lift is equal across the disk.
Dissymetry of lift was discovered by a Spaniard...
Juan de la Cierva - Wikipedia, the free encyclopedia
Juan De la Cierva (21 September 1895 – 9 December 1936) was a Spanish Civil Engineer and pilot. His most famous accomplishment was the invention in 1920 of the Autogiro, a single-rotor type of aircraft that came to be called autogyro in the English language. After four years of experimentation, De la Cierva developed the articulated rotor which resulted in the world's first successful flight of a stable rotary-wing aircraft in 1923 with his C.4 prototype.
Dissymmetry of lift - Wikipedia, the free encyclopedia
Dissymmetry of lift in rotorcraft aerodynamics refers to an uneven amount of lift on opposite sides of the rotor disc. It is a phenomenon that affects single-rotor helicopters in lateral flight, whether the direction of flight be forwards, sideways or in reverse.
To put Cierva's discovery in simpler language...
A rotor system consist of a central hub and the rotor blades. Assume two blades for now. When in motion we have one blade moving into the airflow but the other blade actually retreating from the same airflow. Cierva attended a 1922 Madrid
Don Quixote production with an operating windmill on stage. He noticed that the windmill's blades flapping slightly through each revolution. At that time, all autogyro rotor systems were rigid, in blades and in how they attach to the hub. Cierva decided to hinge them and the result: When one blade is moving into the airflow it would flap upward, losing some lift. The other blade which is in retreat from the airflow would flap downward, producing lift. The laws of physics took over and both blades would balance each other out. Cierva's discovery and how to compensate for the autogyro's unique aerodynamics allowed the helicopter to hover
AND to have forward speed greater than two-digit mph. The 'articulated rotor' was that hinge system to allow the blades to flap, or to be flexible in their motions.
As helicopter development improve in performance over time, thanks to Cierva, loading weight inevitably increases and that led to the addition of additional blades to improve lift capability but because of the rotor hinge system, the entire rotor assembly itself increases in mechanical complexity and weight. Increased mechanical complexity increases manufacturing and maintenance costs. To keep manufacturing and maintenance costs under control, keep the two-blade configuration but increase engine power and blade length. There has to be balances for all factors, from economics to mechanical engineering, and they all must comply with the laws of physics such as a variable rotor length development...
Helicopter Blade Technology - Variable Length Rotor - Video - Breakthrough Awards - Popular Mechanics
Helicopter performance depends on the length of the rotor blades. For heavy lifting, a large rotor works best, but short blades reduce drag and ultimately allow for higher maximum speeds. Farhan Gandhi, a Penn State University professor of aerospace engineering, has devised an elegant, simple way to achieve both configurations in the same aircraft, using the same rotor.
A rotor blade that changes length has been a long-contemplated, never-achieved goal.
It may be counterintuitive, but higher helicopter speeds require fewer rpms, so conventional rotorcraft—such as this Black Hawk—could also benefit. The rotor would be 54 ft. at 258 rpm (maximum engine power). But the blades could be shortened to 40 ft., allowing the helicopter to fly through urban areas or land in tight quarters.
So preference for a two-blade rotor system over three- or four- is not about lift, which greater blade count do provide, but about mechanical complexity and commensurate costs. Proof of this is in the AH-1Z Super Cobra model...
AH-1Z Viper - Wikipedia, the free encyclopedia
The AH-1Z's new bearingless, hingeless rotor system has 75% fewer parts than that of four-bladed articulated systems.
...And many other four-blade rotor systems out there...
Aircraft in Detail - Helicopter Rotorhead Image Gallery Index
Eurocopter AS365N Dauphin 2
Four-blade hingeless main rotor, Starflex glass-fiber/carbon-fiber hub.
Eurocopter EC155B (AS365N4)
Five-blade hingeless main rotor, Spheriflex glass-fiber/carbon-fiber hub.
Eurocopter EC665 Tiger
Four-blade hingeless FEL main rotor consisting of only 24 parts (w/o bolts and bushings).
Hindustan Dhruv (ALH)
Four-blade FEL hingeless main rotor head with fiber-elastomeric bearings sandwiched between two CFRP star plates (same technology as EC665). Blades are manually foldable.
Sikorsky H-53 Sea Stallion (S-65)
Six-blade fully articulated main rotor with titanium and steel hub. Hydraulically folding blades.
Sikorsky H-60 Blackhawk / Seahawk (S-70)
Four-blade articulated main rotor with one-piece forged titanium head and elastomeric blade retention bearings.
Notice the difference between the two Sikorskys and the rest?
What is this hingeless rotor system when there is a need for each blade to have some independent flexing and the blades balance each other out as the laws of physics demands to eliminate 'dissymetry of lift' phenomenon?
The laws of physics does not say there must be a hinge system. The laws of physics say that if we want to eliminate the 'dissymetry of lift' phenomenon, we must allow each blade to have independent flexing movement. How to do that is our problem. Cierva created the hinged rotor blades. Modern materials science give us --
COMPOSITE. Both solutions applied to the same problem. Composite materials allowed rotor blades to flex as the laws of physics demands, reduces hub mechanical complexity which reduces manufacturing and maintenance costs and allow greater than two-blades rotors.
The AH-1Z Cobra model is a four-blade rotor system and is %75 mechanically less complex than its predecessors. We could have remained with a two-blade system but be hingeless and composites but why should we when a hingeless composited four-blade system give us additional performance benefits at minimum mechanical complexity increase? Improved performance, reduction in mechanical complexity out in the field and still obey the laws of physics.
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