# What would happen if I bank a helicopter then pull hard on the cyclic?

Prompted by Simon's response to my question here, I will ask another question about reality.

If I:

2. Pitch down slightly to accelerate, then slowly increase collective to gain speed until max collective is applied and the airspeed is near Vne
3. Roll the helicopter to about 70 degrees of bank
4. Pull back hard on the cyclic

(Basically it can be described as trying to fly a Red Bull race in a helicopter)

What would happen?

• I doubt these are attempted anywhere Vne, but it is pretty cool to watch the Redbull Helicopter do things no other helicopter can do, including extreme bank (complete rolls). Mar 9, 2017 at 15:28
• Possible duplicate of Can a helicopter stall? Mar 9, 2017 at 16:49
• Not a duplicate at all. This question asks about maneuvering a helicopter near Vne at an extreme bank angle. Mar 9, 2017 at 17:02
• Are you trying to stay in a level turn at 70 degrees AOB? Are you familiar with the term "retreating blade stall" as it applies to helicopters. Mar 9, 2017 at 19:29
• What does max collective mean? Max permiites lower, lever fully up or something else? Mar 10, 2017 at 20:52

I can't provide references specific to this manoeuvre. The main texts on helicopter dynamics only generalise since such a manoeuvre isn't flown in real life or tested during certifications.

When you raise the collective, you increase the pitch of the all of the blades together. In most flight regimes, this means increased angle of attack and therefore lift.

The cost of producing lift is drag which always increases. So, there is a direct relationship between the collective lever and power required from the engine.

As you continue to raise the collective, AoA and lift will increase until you reach a point where the power required to overcome drag exceeds the rated power of the engine. Most helicopters permit operation beyond the maximum for a short time, e.g. 2 or 5 minutes, typically during take-off. Continue to increase AoA beyond this limit and drag will exceed power available and the rotor RPM will drop (a reduction in rotor RPM caused by drag exceeding power through too much collective is known as "droop").

As RRPM decreases, so does lift and the helicopter will descend. The relative airflow into the disk now has a greater horizontal component and the angle of attack will increase, either causing yet more drag or stalling the rotor.

So there is some point, before the collective is pulled fully up where maximum lift is attained. Beyond that, lift reduces until recovery or a stall. The only time I have ever raised the collective fully is during "full and free" movement checks with the engine off as part of pre-flight.

From VNE in level flight, you roll into a 70 degree bank.

The TRT( total rotor thrust) is always acting perpendicular to the plane of the rotor disk. Since you are in a bank, and I assume it is at constant altitude, there is a large horizontal component of the TRT to maintain the acceleration in the turn and a large vertical component to oppose gravity and maintain altitude.

This requires a lot of power which means a lot of collective and a lot of drag. I don't know for the AH-6, maybe there's a chart relating bank angle and speed to power but let's just say, your collective is going to be somewhere near the max lift point with a manoeuvre like this.

Since you are now accelerating with max power, your speed will decrease. Therefore lift will decrease and since you are at or near max power, you will begin to descend.

So far, this is probably recoverable simply by rolling level and reducing collective until back inside the performance envelope.

The second part is where it definitely will go wrong. In all helicopters with a non-rigid head, including the AH-6, the disk will adopt a new plane of rotation rapidly. There is then a significant delay before the fuselage adopts a new attitude which puts the TRT perpendicular with the aircraft Z axis.

Pulling hard on the cyclic will very rapidly put the disk into a new plane of rotation which has a large angle between the plane of rotation and the fuselage. Additionally, the disk loading will increase dramatically and the blades will be forced downwards. On an articulated head such as that on the AH-6, droop stops will prevent the blades from bending down so much that they fold.

Hitting the droop stops a little is uncomfortable with a lot of vibration. Pulling hard on the cyclic at VNE in a 70 degree bank at or near max power may cause failure of the droop stops or blades or cause the static droop stops to contact the mast possibly leading to rotor separation.

Let's assume that there is no failure. The plane of rotation will be at the maximum permitted by the physical limits of the flapping hinges which is greater than the angle between the plane of rotation and the fuselage.

Therefore, I would expect a hard pull on the cyclic to result in a blade hitting the tail or the top of the cockpit. Either results in destruction of the aircraft, either as it breaks up at that point or when it hits the ground 10 seconds later.

First post here. I'm not a pilot, but this is how I see it happening with my understanding of helicopter forces.

Collective is up a fair bit since we've been raising it. VNE is approaching fast, and we may be starting to feel a retreating blade effect, so we might be naturally pitching left ever so slightly. If we propogate that to 70 degrees, then quickly pull back hard on the cyclic, with the collective never changing, the main rotor will pitch up in front and down in back to an extreme, and the blades will slow down considerably with all that drag. You will also experience inverse torque and your hull will begin to twist right abruptly unless extreme action is also taken on the rudder, throttle, and collective to mitigate the sudden change in vector momentum. You will also pitch wildly to the left even more, which will further confuse your vector of travel, adding strain on your hull, main rotor, and drive shaft.

Imagine pulling up, tilting left, and spinning right. Now you're sort of flying sideways/backwards, ~270 degrees from your previous travel vector, and still spinning your hull to the right.