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Qantaslink Fokker 100 overrun - Newman, W.A.


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Newman had 142mm for the 24 hrs up until 9:00AM Thursday 9th January 2020. The Qantaslink Fokker (QF2650) landed at 7:15AM with heavy rain still falling.

 

Obviously the PIC and his FO didn't have enough experience of what "heavy rain" means in the Pilbara, nor perhaps did they have enough experience, as regards aquaplaning.

 

It seems pretty obvious the brakes didn't have anywhere near the effect, that they expected.

 

Quite embarrassing - and costly too, as the roads around Newman were closed, and they didn't have the right towstrap on hand to be able to haul the Fokker back onto the tarmac.

 

https://www.airlineratings.com/news/qantaslink-flight-overuns-newman-airport-heavy-rain/

 

Passenger video, with Geoffrey the local expert, having his 0.02c worth - https://7news.com.au/news/aviation/qantas-plane-slides-off-runway-at-newman-airport-due-to-cyclone-blake-downpour-c-640039

 

 

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I'm currently working in Newman. It was sideways torrential rain at the time with the 'eye' of ex TC Blake heading south past the town. I have always believed the runway at Newman needs to be a bit longer for this sort of thing. The last 'landing' I was a pax in ended up as a missed approach due to a 180 degrees switch in wind direction during the roundout. I had my nav app running at the time. Screenshot attached. Good on that crew for going round.

 

1085712642_missedapproach.thumb.jpg.fbf371dddd1ef54312ba4fa3da5a216c.jpg

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I wonder if they deployed the reverse thrusters? I looks like they are fitted. 

 

I flew Alliance when they had them fitted to their F100's for just such an occasion.

 

They tested them a few times,  but generally didn't use them (or need them) as they burnt more fuel.

 

 

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Reverse thrust is only effective if used soon after landing. It also blankets the rudder and if you are aquaplaning, rudder is the only directional control you have. Grooving of the runway surface is helpful. Nev

 

 

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I don't recall seeing any of the runways in the North of W.A. with grooving. They're all just regular highway grade, smooth asphalt. 

 

The tarmac water runoff rate in heavy rain is quite slow, because the runway camber is quite flat, as compared to highways.

 

There would have been a lot of water on the runway surface in this case, under the rainfall and wind conditions shown, and it would have been quite a "hairy" braking effort.

 

http://aaa-asphalt.com.au/our-work/

 

 

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Tyre pressure and speed are the main factors. You also avoid "squeeker" landings and aim to plant it a bit firmer to prevent rubber reversion by superheated steam that just shaves off rubber very quickly even though you have no brakes on.  You also need things like chined tyres on the nosewheel to keep water out of the engines .Nev

 

 

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In fairness you've got to go a bit easy on these blokes. It's pretty "IFFY" operations at times in those downpours with shifting  strong winds.. Not everything is textbook or you just wouldn't operate. for a few months. . . Pilots DO have to FLY these planes and like any other they don't fly themselves. Nev

 

 

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Always easy to critique these accidents from the comfort of an armchair, but with winds gusting 35kts plus heavy rain, it would not have been a pretty sight on approach to Newman. The obvious lesson for we recreationals is that it's smart to avoid these conditions.  Rain on the windscreen makes a world of difference to ones estimations of distance and speed, but cyclonic downpours are something else.

 

I hope the crew are not 'hung out to dry' by both their company and the regulator.

 

 

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I've put a jet down a few times in atrocious conditions like these guys experienced, it's very challenging with a degree of the Unknown & pucker factor! These pilots are human not machines, I hope the boffins who would want blood will remember that! 

 

 

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I wonder if they deployed the reverse thrusters? I looks like they are fitted. 

 

I flew Alliance when they had them fitted to their F100's for just such an occasion.

 

They tested them a few times,  but generally didn't use them (or need them) as they burnt more fuel.

 

I would be surprised if Alliance avoid the use of reversers to save fuel - it increases maintenance costs when you use more braking.  The fuel use is minuscule and at the lower end (idle reverse) there is absolutely no increase in fuel use.  No economic reason to avoid their use.

 

 

The procedure for this F100 operator is to use reversers when available.  However, please note  - reverse thrust is not considered in landing calculations, it is there for economic reasons, reduced wear and tear.  Most of this operators F100 do not have auto brake (IIRC, NHY is ex Avianca and is not equipped), they do all have ABS.  All the aircraft are equipped with auto deploying lift dumpers.  Both reversers and lift dumpers will be ineffective if main wheels don’t reach a speed equivalent to aprox. 80 knots IIRC, as there is a logic box that mostly prevents them from operating in the air.

 

The comments below are speculative.

 

 Two possible technical factors of relevance are a level of aquaplaning that prevents or delays sufficient main wheel speed to deploy armed or set lift dumpers and which prevents selection of reverse thrust - this can greatly increase the landing roll.  A possible operational factor would be inadvertently landing long under challenging conditions.  This operator is right on the ball with stabilised approaches and sticking to the numbers, I think it unlikely that a high approach speed would be a factor - unless they had concurrently dealt with a wind shear alert (not warning) during the approach, in which case they might be at the higher end of the tolerance.  There is no PAPI and no precision approach for Newman, so vertical guidance is limited.  It’s unlikely (I only mention it due to a lack of information on the circumstances), but sometimes in the Pilbara a wind shear event on finals with an attempted escape manoeuvre is so great that the aircraft still touches down from the go around.  A previous Pilbara case of a dry microburst with an F100 bent the aeroplane, but there was no overrun.   Conceivably, a different result with a contaminated runway could see an overrun.

 

 

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Tyre pressure and speed are the main factors. You also avoid "squeeker" landings and aim to plant it a bit firmer to prevent rubber reversion by superheated steam that just shaves off rubber very quickly even though you have no brakes on.  You also need things like chined tyres on the nosewheel to keep water out of the engines .Nev

 

I don’t think you can get rubber reversion with dynamic hydroplaning, you need to lock the wheels to get rubber reversion hydroplaning - otherwise the necessary friction simply rotates the wheel.  This is most commonly encountered when an aircraft is in dynamic hydroplane, ABS braking is ineffective and the parking/emergency brake is applied to manage a perceived service brake failure.  You can see that it has happened by the steam cleaned wheel tracks on the runway as well as the chewed up tyres.  Usually a secondary effect of locking the brakes is retraction of lift dumpers, after some type specific delay.  So the sequence may be of heating the tyres first, retracting the lift dumpers and then continuing with locked wheels and less water displacement.

 

 

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Sorry Sacc That is definitely NOT so. While it seems unlikely, the wheels often rotate slowly backwards while the superheated steam is being produced, but most times it just removes heaps of rubber with a characteristic appearance so it's easy to identify. Without ABS you are going  get tires blowing pretty often. It's a must have but without wheel spin up it's not working. Nev

 

 

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Sorry Sacc That is definitely NOT so. While it seems unlikely, the wheels often rotate slowly backwards while the superheated steam is being produced, but most times it just removes heaps of rubber with a characteristic appearance so it's easy to identify. Without ABS you are going  get tires blowing pretty often. It's a must have but without wheel spin up it's not working. Nev

 

I'll let someone else say it;

 

"Reverted-rubber aquaplaning.  This occurs when a wheel 'locks up' (or stops rotating) [emphasis added] and is dragged across a wet surface, generating steam.  The steam pressure lifts the tyre off the runway surface.  Heat from the steam causes the rubber to revert to its unvulcanised state, leaving a black, gummy deposit of reverted rubber on the tyre.  Reverted-rubber aquaplaning will also typically leave distinctive marks on the runway, with black marks on the edge of the contact patch and a clean section in the middle where the runway has effectively been steam cleaned.  This type of aquaplaning can occur at any speed above about 20 knots and results in friction levels equivalent to an icy runway." - ATSB

 

So I guess I'm not alone in my wacky ideas.  Also take a look at page 16 on in this study; ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19680010151.pdf .

 

I'm willing to be convinced of your thesis - do you have data to support your thesis?

 

I'm not sure I understand your comments about ABS, discussion of the F100 system may shed light.

 

In the Fokker 100, there are three modes of anti-skid operation;

 

Touch down protection:  All six pressure valves remain in the dump position until seven seconds after the ground/flight mode changes to ground mode, or any wheel reaches 20/40 mph (20 or 40 mph depends on mod status).  You could apply full brake when landing and the wheels would have no braking applied.  Lift dumpers (if available) should normally be manually deployed on wet runway, but ground mode is needed.  Approx. 80 knots wheel rotation is also needed for auto deploy.  Typically 7 seconds  after touch down on a contaminated runway, 3 to 5 seconds after mode change before the brake pressure dump valves are released.

 

Skid detector: Kicks in at 12 mph wheel rotation speed.  Each wheel has deceleration monitored and excessive deceleration causes pressure release on that wheel to keep it from exceeding the skid threshold.

 

Locked wheel prevention:  Above 20 mph wheel speed, locked wheel circuits are in stand-by.  If an outboard (inboard) wheel speed is 30% below the opposite outboard (inboard) wheel speed, a full pressure dump is applied to the wheel.  This system is inhibited below 20 mph.

 

In the F100, dependant on the ground/flight controller fitted, a guarded anti-skid off switch is on the pedestal next to the FO pitch trim wheel, allowing anti-skid disablement.  The parking brake is not an emergency brake in the F100, it serves to retain applied brake pressure.  Instead an alternate brake system will operate without pilot intervention if the primary brake system on that side fails.  This isn't obvious except by the annunciator, almost full capability is retained, but each side is treated as one unit for anti-skid, instead of each wheel.

 

I can see no reason to have tyres blowing fairly often with anti-skid inoperative.

 

In this system, the anti-skid system allows brake application without wheel rotation.  Locked wheel protection doesn't operate if both outboard (inboard) wheels are turning or not turning within 30% of each other - as may be the case with extreme hydroplaning.  Application of brakes on touch down with aquaplaning can result in locked wheels from seven seconds after ground/flight enters ground mode until the aircraft stops.  As in, it is possible, particularly if auto deploy is selected on lift dumpers, as they may fail to reach the 80 knot  deploy threshold, before the brakes are applied, preventing it from happening.  One reason why lift dumpers should be at manual for a wet runway.

 

With regard to the "characteristic appearance", all my knowledge and experience says that is of an area of reverted-rubber corresponding to the contact patch of a locked wheel.

 

I've never seen any data to support rotation of the wheel in reverted-rubber hydroplaning (let alone backward) and it is contrary to my experience in investigating such matters.  What may sometimes occur is a patchy series of contaminations, causing multiple areas of reverted rubber, as the wheel spins and then locks again - this may perhaps give some the impression of rotation, but these are separate cases.

 

But, as I say, I'm open to being convinced otherwise - though my previous experience and training says it is not so.

 

Here is Michelin aircraft tyres take on hydroplaning;

 

"10.3.4. Dynamic Hydroplaning is a high speed phenomenon which occurs on any surface and

requires a minimum fluid thickness.

10.3.4.1. Considering the various fluids reasonably encountered by aircraft tires, slush is

the most likely to cause dynamic hydroplaning. It is less dense than water, but is

deeper due to its viscosity. Slush, along with snow or ice, deserves particular

attention.

10.3.5. Viscous Hydroplaning results when a thin film of fluid (water) on the runway becomes a

lubricant. It may mix with the contaminants present or the water alone may be sufficient

if the surface texture of the runway is smooth as on a painted portion of the runway

markings. Generally the irregular condition of the runway surface is sufficient to break up

this film.

10.3.6. An aircraft tire experiencing hydroplaning may form an area of tread rubber reversion or

skid burn in the tread due to lack of wheel rotation [emphasis added]. This area will be oval in shape similar

to a flat spot. If the reinforcing ply (bias) or protector ply (radial) is not exposed the tire can

be left in service. If any vibration resulting from the flat spot is acceptable, the tire can be

left in service.

NOTE: The most effective method to minimize the effects of water on traction is to

reduce the water depth. Many airport runways are cross-grooved to improve

water drainage."

 

Kind regards,

 

Paul

 

 

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Re re slow turning in a rearwards direction, I've personally seen imagery of it in training material Part of my training with one of Australia's biggest airlines at the time, and when these things were done comprehensively. The wheel is certainly NOT locked as it  CLEARLY rotates slowly backwards .Grip on the runway...... obviously has none due to the lack of adhesion. due steam and water. The hot steam acts at the front of the wheel where the water is coming from.

 

 Blown tyres without antiskid working.? Almost UN preventable on heavy aircraft unless you hardly brake at all and can happen in dry and normal conditions.

 

  It's a known accepted and recommended technique to land "positively" to prevent flat spotting on "wet " runways (achieve wheel spin up) in low adhesion situations. You don't try for a "greasy" landing .

 

  The grooving of the runways that eventually happened after a lot of pressure was applied to the government were along the runway not across it at Sydney on rwy 16. where I had personal experience of "severe" aqua planing for at least 1/2 km before any wheel achieved ANY grip at all and could not use reverse thrust as it would have cancelled out the rudder effect which was all I had to keep the aircraft in the centre of the runway.. AS far as the wheels were concerned It might as  well have been "black Ice".  Absolutely NO grip at all.

 

  Better adhesion is obtained as you slow down in an aquaplaning situation.. Speed, water depth and tyre pressure are considered factors and I guess tread depth as well. Nev

 

 

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Re re slow turning in a rearwards direction, I've personally seen imagery of it in training material Part of my training with one of Australia's biggest airlines at the time, and when these things were done comprehensively. The wheel is certainly NOT locked as it  CLEARLY rotates slowly backwards .Grip on the runway...... obviously has none due to the lack of adhesion. due steam and water. The hot steam acts at the front of the wheel where the water is coming from.

 

 Blown tyres without antiskid working.? Almost UN preventable on heavy aircraft unless you hardly brake at all and can happen in dry and normal conditions.

 

  It's a known accepted and recommended technique to land "positively" to prevent flat spotting on "wet " runways (achieve wheel spin up) in low adhesion situations. You don't try for a "greasy" landing .

 

  The grooving of the runways that eventually happened after a lot of pressure was applied to the government were along the runway not across it at Sydney on rwy 16. where I had personal experience of "severe" aqua planing for at least 1/2 km before any wheel achieved ANY grip at all and could not use reverse thrust as it would have cancelled out the rudder effect which was all I had to keep the aircraft in the centre of the runway.. AS far as the wheels were concerned It might as  well have been "black Ice".  Absolutely NO grip at all.

 

  Better adhesion is obtained as you slow down in an aquaplaning situation.. Speed, water depth and tyre pressure are considered factors and I guess tread depth as well. Nev

 

I don't know what you saw in training material and I certainly have absolutely no doubts about your sincerity, integrity, skills and professionalism.  But you've given me nothing I can examine and I do need something a bit more to go on.  I have seen  some films of hydroplaning tests that may give that impression due to camera synchronisation artifacts.  Tyres I have examined after rubber-reversion hydroplaning have mostly had single contact patch areas of rubber-reversion, in one case they had several, representing multiple events with patchy areas of shallow water and the operation of that anti-skid system.  I've never seen any damage that would correspond to slow rotation whether forwards or backwards.  Hot steam should not be acting at the front of the contact patch where the water is coming from, that's the cooled side.  I've seen DFDR showing wheel rotation ceasing at a point corresponding (but not exactly, the data isn't that accurate) to the white marks of rubber-reversion hydroplaning starting.   If your training film *told* you that these were the conditions of rubber-reversion hydroplaning, I can only say, your training film was wrong to do so and you should re-evaluate incorporating this material in your personal model of how things work.  But give me some reasonable reference to support your position and I'll be happy to do the same.

 

I completely agree with the technique of a firm landing and avoiding a 'greaser', though more for having the maximum stopping distance.  Unless you have solid tyres, it shouldn't be making any difference to whether or not you hydroplane in the first place and won't prevent subsequent hydroplaning.  I do not accept the existence of rubber-reversion hydroplaning without prolonged wheel lock.  With the improvements to anti-skid systems in the early eighties it is hardly ever seen in large transports today, except with emergency locked wheel  braking.

 

I still see no reason to expect fairly high rates of blown tyres with hydroplaning large transports and anti-skid inoperative.  But I'm guessing now that you had dry runways in mind.  Certainly more than with anti-skid, but I'd expect the thermal fuse to do something most times before the tyre blows.

 

I must confess I once hydroplaned a good two and half km in a lightly loaded condition (150 tonnes) - it was very interesting and quite concerning too - nice that I had more than 3 km available.  I'd say the use of reversors with regard to rudder effectiveness would be type specific, but I would note that you are not left without directional control with loss of rudder effectiveness, you have differential reverse thrust available and the issue of prohibited n1/n2 blade flutter zones in reverse is best left for maintenance to deal with after you stop.  In some large transports, failing to use reversors means you don't have any lift dumping, which is hardly helpful.

 

Yes, speed, water depth and tyre pressure are considered factors, as well as surface texture.  Screed surfaces greatly increase the water depth requirement, but are hardly used due to the stone throwing aspects and so on.  Grooving does much the same thing, longitudinal is a hell of a lot smoother than crosswise and more durable.  The essence of predicting commencement of total dynamic hydroplaning is Horne's formulae.

 

dynamic hydroplane ground speed (knots) =  9 x tyre pressure (PSI)^-1.   Load/weight makes no difference - for a typical F100, it's 146 knots.

 

Robert Horne did about twenty years of experimental research on hydroplaning in the NASA, using full size gear on a test sled.  In 1963 he thought the (reverted-rubber) cleaned skid phenomenon was due to water under high hydrodynamic pressures scouring the area, but with more research, came to understanding the steam aspect.  Due to improved anti-skid systems, you hardly see it today - except with emergency systems that don't have effective anti-skid or defeat anti-skid.

 

What really happens in rubber-reversion hydroplaning?

 

You have up to three zones involved in hydroplaning.  In total dynamic hydroplaning,  the entire tyre is removed from contact with the underlying surface - the dynamic hydroplaning zone extends from the area of tyre contact with the water and there is neither a viscous hydroplaning zone nor a zone of surface contact (or a bow wave).  In hydroplaning, this zone is always present , but its trailing edge moves forward, first being replaced by the viscous zone, then by the contact zone behind the viscous zone.  As speed reduces, the contact zone increases in size, displacing both the viscous and dynamic zones until we have full contact again.  Also, as speed decreases below total hydroplaning speed, a bow wave is formed as part of the dynamic hydroplaning zone. 

 

image.png.4347283539235dbcfe016252b539fdf2.pngdrawing: Gerad van Es, Netherlands Aerospace Centre. Zone borders change with conditions.  Zones 1&2 reduced in R-R planing.

 

In rubber-reversion, the wheel is locked and the area of the contact zone (the third zone) is heated whilst being supplied with water from the viscous zone, which is turned into steam.  This can only - repeat - only - occur with the wheel locked.  The reverted rubber tends to form a skirt about the water under the contact zone, retaining water to create steam and reducing friction in much the manner of a hovercraft.  The steam is towards the rear of the tyres interaction with the water and the surface, not at the front.

 

There just isn't a way to do it with a rotating tyre, forwards or backwards, because the conditions for it no longer exist - at least, in real aircraft so far.  Maybe if you take things vastly outside of real world parameters you might be able to heat the whole tyre whilst it slowly moves in a forward rotation.  And maybe you can drive it backwards and have the same thing happen.  But that's so far beyond scope it isn't worth looking at.

 

Films of  total dynamic hydroplaning tests will often appear to show backwards movements as the wheel slows down to a stop (which it will do, if total dynamic conditions remain long enough and no one invents frictionless bearings) - it is due to the shutter synchronisation issue.  It's like how you can use a stroboscope on a propellor when calibrating a tacho and have the propellor appear to move backward or stop.   It isn't real, it is an illusion.

 

I would like to say something about how to deal with hydroplaning.  If a go-around isn't an option, reversers are a good option, provided you can maintain directional control (not prohibited by flight manual)  - you can always retract them if you have to, but you can't apply them earlier than you did.  But aerodynamic braking works, lift the nose up with lift dumpers to manual if you have them.

 

As a matter of interest, you can usually tell with the combination of DFDR data and the weight and balance, not only if hydroplaning occurred, but what kind of hydroplaning too.

 

Warm regards,

 

Paul

 

 

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The trouble is, Paul, that we have just lost the interest of 99% of the people on this forum. with anything lengthy, complex and not really related to their "scene" ..  Anyhow, Reversing  of the side engines on a REAR engined jet blankets the rudder..  That's why I couldn't do it. That doesn't happen with underwing..

 

 Yes most flat spotting is with wheel lock caused by brake application. I didn't say all wheels went backwards just that some CAN  (just in passing, not to make a big deal of it) and in that case brakes are not applied, of course. As to the possibility of strobing like in John Wayne stage coach wheels as they slow up, being mistaken   NO.  I 'd  absolutely rule  that out  in the circumstances of how it was presented. Tyres can suffer damage without brakes on. Hence the" firm landing" recommendation in wet conditions. which you acknowledge is fairly well accepted and practiced.  Part of your pre landing is to check brake release light REL Anti skid check.' and brakes OFF for obvious reasons one doesn't want to land with brakes on or unknown anti skid INOP.

 

  In U/L s brake check  prior to landing is mainly make sure brakes are OFF and your feet aren't positioned as to apply them accidently when using rudder.. Aquaplaning??  With a maximum stall speed of 45 knots it's academic

 

   Wheel hydroplaning is a little similar as being able to water ski on your feet. It's hydrodynamic. The film of water hasn't time to go out the front and sides (IF you are fast and it's deep, so some goes underneath, lifts you a tiny bit and you lose your grip on the surface. Nev.

 

 

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The trouble is, Paul, that we have just lost the interest of 99% of the people on this forum. with anything lengthy, complex and not really related to their "scene" .. 

 

Dear Nev, as you've demonstrated, once an incorrect idea gets in, it's pretty hard to get it out later. I'd rather do something about it now.  I did make a short observation, which you did not accept.  All three forms of hydroplaning are relevant to light aircraft.  The facts are complex - it is unhelpful to muddy the waters with incorrect notions.  The causes and mechanisms you have proposed are not correct.  This helps no one.   I would much rather that you had simply taken the opportunity to check your facts rather than assert it is "definitely not so" and  introduce new errors in defence of the first mistaken notion.  I beg you, please take a look and see if you can find something to substantiate what you are saying and arrive at a new understanding.   Or conversely, you may end up educating me if you have something substantive.  I'm really not trying to give you a hard time, I am concerned that mistaken notions embed themselves in pilots and are difficult to extract later.  Some are harmless - this is not such a case.  A light aircraft pilot really needs to know from the begining how this works - precisely because they won't have much experience with it and are most likely to have it in conditions that are very demanding for their skill levels.  Malarky about this not being a locked wheel condition is exactly the kind of thing that could cause them a greatly extended hydroplaning distance off the runway to who knows where.    

 

Anyhow, Reversing  of the side engines on a REAR engined jet blankets the rudder..  That's why I couldn't do it. That doesn't happen with underwing..

 

I'd say you should be using them if the flight manual allows it - you can always retract them if you don't have enough rudder authority at idle reverse.   In the case of the F100, the flight manual not only allows it on wet/contaminated runways, it requires it, unlike dry runways.   I'm not aware of any rear engined aircraft AFM that prohibits reverse thrust with wet/contaminated runways, some will advise idle only for rudder blanking reasons - the F100 AFM does not. It also needs to be noted that if you do NOT use both thrust reversers on an F100 and the wheels have failed to spin up sufficient to auto deploy the lift dumpers, you are not going to get lift dumpers without doing some fiddling.  Yes, rudder blanking is a risk that requires consideration - it is not, however, a good reason to completely avoid reverse thrust.  At least for F100, DC-9 and derivatives, 727, VC-10 - maybe there are biz jets where it is prohibited?  Mostly, AFM and FCOM will mandate thrust reversers for landing on wet/contaminated runways.  Where people run into trouble in rear engine large transports is in using excessive reverse thrust.

 

I would have to say this rudder blanketing idea seems rather overstated to me - but I accept it may be very relevant to some type you have flown that I don't know very well.  (I'm curious as to what that might be)   If you are having trouble maintaining directional control in any large transport certified post 1975 as a result of idle reverse thrust, either something has gone wrong with the certification process or you are operating beyond the certification limit.  In cases I know of where people have gone on excursions due to loss of directional control, they've exceeded the cross wind limit and operated at maximum reverse thrust without reducing to idle when they've lost directional control.  What should be happening is that if directional control is lost, reversers go to idle (and not off) until you regain the centre line.  

 

Usually, in RPT, for a wet/contaminated runway, you need to factor the landing distance by 1.92 and use the reversers.  Landing without using them usually takes you out of certification parameters.

 

 Yes most flat spotting is with wheel lock caused by brake application. I didn't say all wheels went backwards just that some CAN  (just in passing, not to make a big deal of it) and in that case brakes are not applied, of course.

 

I'm sorry, but what you said was "You also avoid "squeeker" landings and aim to plant it a bit firmer to prevent rubber reversion by superheated steam that just shaves off rubber very quickly even though you have no brakes on. " and "While it seems unlikely, the wheels often rotate slowly backwards while the superheated steam is being produced, but most times it just removes heaps of rubber with a characteristic appearance so it's easy to identify."

 

Both of these statements are untrue.  You do not - ever - get rubber reversion by superheated steam... ...even though you have no brakes on.

 

You do not - ever - have wheels slowly rotating backwards whilst superheated steam is being produced

 

Your understanding is incorrect.  You have conflated different types of hydroplaning.   It is true that in total dynamic hydroplaning (no viscous or contact zones), if speed is maintained well above the total dynamic hydroplaning speed for long periods, wheels can rotate backwards.  This is a hydrodynamic lift effect (nought to do with steam), the centre of lift is forward of the axle, causing reverse rotation force - it has been demonstrated to *stop* rotation in full size testing.  I'm not aware of reverse rotation ever being demonstrated full size in testing - but at NASA Langley in 1968, a scale wheel was used with a circular rolling road to demonstrate this effect.  Footage of this was used in training films - but it has nothing to do with the rubber-reversion hydroplaning case which only occurs with locked wheels.  

 

As to the possibility of strobing like in John Wayne stage coach wheels as they slow up, being mistaken   NO.  I 'd  absolutely rule  that out  in the circumstances of how it was presented.

 

That being the case, the training film was wrong.  I've given you verbatim quotes that tell you that this is wrong - and they are only a fraction of the engineering sources saying that this is wrong.   You'll also find many research papers that also say that it is wrong.  Remember, the issue is what you said about rubber-reversion hydroplaning.

 

Tyres can suffer damage without brakes on. Hence the" firm landing" recommendation in wet conditions. which you acknowledge is fairly well accepted and practiced.  

 

No, that is not the reason for the recommendation.  Your idea about damaging tyres with superheated steam without the brakes on has no foundation.  The reason you need a firm touchdown is that you need wheel spin up to enable operation of systems such as lift dumpers and brakes.  On initial contact you have a good chance of displacing the contaminant and achieving this.  The other reason is the greatly increased stopping distance that is required - a gentle touch down uses up much more of the runway if the screen height is respected.

 

Part of your pre landing is to check brake release light REL Anti skid check.' and brakes OFF for obvious reasons one doesn't want to land with brakes on or unknown anti skid INOP.

 

Indeed, and in most large transports measures are taken to prevent the application of brake early in the landing.   Which is one of the reasons you need a firm touchdown to spin the wheels.

 

In U/L s brake check  prior to landing is mainly make sure brakes are OFF and your feet aren't positioned as to apply them accidently when using rudder.. Aquaplaning??  With a maximum stall speed of 45 knots it's academic.

 

Well, it would be, if your understanding was correct.  I'm most awfully sorry, but your understanding is not correct.

 

At any tyre pressure below 34 PSI, 45 knots *ground speed* is enough to achieve total dynamic hydroplane.

 

With an approach speed of 58 KCAS for a J160, there is absolutely no reason to dismiss 'aquaplaning' for U/L on the basis of stall speed.

 

A J160 has 26 PSI on the mains and 20 PSI on the nose (though in practice, often less).  That means that on landing, its speed to achieve total dynamic hydroplaning is 39 Knots for the mains and 34 knots for the nose wheel.   Stall speed is 45 KCAS.  At speeds below 39 knots hydroplaning will still occur.  The speeds for onset of rubber-reversion hydroplaning are even lower.  And this only happens when you are not in total dynamic hydroplane.  Locking the wheels will, if dynamic and viscous hydroplaning is low enough to allow contact, allow for rubber-reversion hydroplaning.  The big deal with this is, unlike rubber reversion in the dry (which gives you about 20% of the braking co-efficient of the non-skid condition), you get next to nothing.  And that doesn't stop until about 10 knots ground speed, at which point you go to a conventional reverted-rubber skid, which isn't a whole lot better.  Not understanding that this is a locked wheel condition - and one that happens at the lower end of speed and contamination depth is a good way to set people up for a runway excursion.

 

Tread depth doesn't change these speeds, it changes the depth at which total dynamic hydroplaning occurs.

 

Regards,

 

Paul

 

 

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You are not interested in what I say except to utterly discredit it. It's not a contest . But you want one, so I'm not interested.. I put something in as a point of interest and you want to make a federal case of everything.   . People tire of this sort of stuff so I'm out.. Nev

 

 

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Paul, your arguments may be suitable for a forum involving large commercial aircraft and heavy jet piloting - but as Facthunter points, this is a Recreational Flying forum, specifically aimed at light and ultralight aircraft owners and users, so a very substantial amount of your information is not relevant to the readers of the forum. 

 

For the readers of this forum (who will possibly, very rarely encounter aquaplaning when landing), I think perhaps the basic instructions in the link below, is adequate enough information for light and ultralight aircraft piloting.

 

https://www.boldmethod.com/blog/lists/2019/02/the-three-types-of-aircraft-hydroplaning-and-how-to-prevent-them/

 

 

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You are not interested in what I say except to utterly discredit it. It's not a contest . But you want one, so I'm not interested.. I put something in as a point of interest and you want to make a federal case of everything.   . People tire of this sort of stuff so I'm out.. Nev

 

Dear Nev,

 

I only commented because I am very interested in what you say and have a great respect for what you say.  If I thought you were a numpty I wouldn't bother.  Unfortunately, your denial of evidence that you were in error has tended to discredit you - that was neither my intent nor my fault and is regrettable.  If instead you had paused to check your facts and acknowledged error, that would have been to your credit.  I'm afraid I'm not the one seeing this as some kind of contest where mistakes can't be admitted.  It seems that you expect to tell others that what they say is "definitely not so" and that that should be the end of the matter - the facts of the matter be damned.   Perhaps an unfortunate approach for someone choosing the name "Facthunter".  Unfortunately, for those with considerable experience and knowledge in a field,  it is commonly difficult to admit error - or to see the reward in doing so.   This is an entirely understandable aspect of human nature.   I've begged you to check your facts - it isn't too late to do so and would be to your credit if you did.

 

Warm regards,

 

Paul

 

 

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Paul, your arguments may be suitable for a forum involving large commercial aircraft and heavy jet piloting - but as Facthunter points, this is a Recreational Flying forum, specifically aimed at light and ultralight aircraft owners and users, so a very substantial amount of your information is not relevant to the readers of the forum. 

 

For the readers of this forum (who will possibly, very rarely encounter aquaplaning when landing), I think perhaps the basic instructions in the link below, is adequate enough information for light and ultralight aircraft piloting.

 

https://www.boldmethod.com/blog/lists/2019/02/the-three-types-of-aircraft-hydroplaning-and-how-to-prevent-them/

 

Thank you, I apologise.

 

That site is indeed ample, particularly if you note the comment below it.  Whilst lighties may be going slower, they also tend to use shorter, narrower strips.  In Australia, probably the greatest risk for lighties hydroplaning is CAVOK into a snow/slush contaminated runway (yeah, I know it doesn't happen often or everywhere), followed by a scud runner looking to get down ASAP who lands on a runway right after a thunderstorm has dumped on it.  One thing from the heavier side that light pilots don't get much training in (if at all), it is in rejecting the landing *after* touchdown.  If light pilots could incorporate that idea into their thinking, it could get them out of a few pickles.  So too with the rejected take-off, the idea of making a decision to continue or safely reject the take-off is something that isn't prominent in recreational training, but a useful one to have in your 'mindset'.  So many make that decision when they advance the throttle, with only the issue of what to do in an engine failure in their mind.

 

regards,

 

Paul

 

 

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I said I'm out..    Don't shout. I have nothing to prove.  Please leave it at that.. .

 

I apologise for shouting.  I did not intend to.

 

I wish you well.

 

regards,

 

Paul

 

 

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