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Pakfa analysis by me!

ptldM3

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This thread is deticated to address some of the concerns people have had with the Pakfa. If you have nothing constructive, and or scientific to add, and if you're here to call the Pakfa "ugly" "junk" "un-stealth" or call others "stupid" such as in the previous Pakfa thread then leave right now.


Some concerns people have had:



Do you understand that your source is russian? of course they are going to make claims like that. the funny thing is... its even evident to a blind person that F-35 and F-22 engines clearly have a huge huge advantage in IR reduction over Pak-FA. Even Rafale and EF have reduced IR then Pak-FA.

As we know the F-22 engine is hidden, like this: http://i231.photobucket.com/albums/ee213/perchatkin/f22_03_106.jpg

Now, the prototype Pakfa used conventional engines like this: http://i231.photobucket.com/albums/ee213/perchatkin/su30mkidetail3.jpg Notice how far back the engines are.

Many have pointed out that the Pakfa (117s) engines give off too much IR. However, it's tucked back similarly to the F-22's engine, with the exception being, the F-22 engine is covered in a 2 dimensional manner while the conventional 117s engine is covered by 3 dimensional nozzles, thus both engines are tucked back, the big difference is the F-22 setup is stealthy, and Contrary to popular belief the F-22 still gives off plenty of backwash.

Take notice of the backwash in this picture:

Example: http://i231.photobucket.com/albums/ee213/perchatkin/F22LowTakeoff.jpg simply can't eliminate that by pushing the engines back several feet.

The F-22 uses other methods too, and it does indeed produce less of an IR signature, but the difference is not big.



Another concerned member had this to say about size:

Without even accounting stealth technology we can determine that since the size of F-35 is 2/3 of Pak-FA F-35 is more stealthy then PAK-FA.

So some beleive the size of the Pakfa will have an adverse effect on it's RCS. However, the B-2 manages to do just fine.



Another concern:


The biggest factor to PAK-FA lesser stealth characteristic is the un smooth geometry found on the belly which F-35 and F-22 have clearly avoided.

Belly or back it doesn't matter, other stealth aircraft have humps too, the difference is their humps are usually located on top of the fuselage. Moreover, the F-35 has a small hump on the belly but an even bigger one on top of the fuselage. Take note of the following examples:

http://i231.photobucket.com/albums/ee213/perchatkin/US_Air_Force_YF-23_Experimental_Fig.jpg .................hump

http://i231.photobucket.com/albums/ee213/perchatkin/F-35JSF_468x278.jpg ..................hump

http://i231.photobucket.com/albums/ee213/perchatkin/b2_bomber.jpg ...................hump

I concede the "engine humps" could be better blended in with the rest of the aircraft, but it's not as bad as many think.

This next picture represents the flat and smooth area's of the under belly:

http://i231.photobucket.com/albums/ee213/perchatkin/0422b89398ed.jpg

Lockheed Martin employee that helped develope the F-22 had this to say about the stealth qualities of the Pakfa:

Key Publishing Ltd Aviation Forums - View Single Post - The PAK-FA Saga Episode X




This is less of a concern than an opinion:

Stop kidding yourself that this and that is not finished! The engine nozzle on production variant PAK-FA is finished and here is the video of it. their are absolutely no plans on modifying anything on the engine as it will take time if their are other things to modify as well and both air force cant afford if they want to meet the dead line.

The real engines are still under development, even Putin has stated the engines have a while to go untell they're finished. If you look at the history of Sukhoi you will see the radical difference between prototypes and production models.

http://4.bp.blogspot.com/_aYAUsn-hXgc/Sl0xUO2cuZI/AAAAAAAAAF4/cWVyPGUDvWs/s320/su27_T10-1.jpg

That was the prototype SU-27.

It will be years before this aircraft enters production. Moreover, Sukhoi engineers are aware of IR signature, aircraft geomery, and so forth. Translation, sukhoi knows better than anyone on this forum.



Moreover, many people are forgetting that the Pakfa is just a prototype, so keep that in mind.

Pakfa developments start here!
 
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Excellent analysis !!!

Especially, the Flanker prototype.
 
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very good analysis....hope others understand...
 
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Good analysis mate.

I agree that PAKFA still has some way to go (especially the engines), but that doesnt mean it will come out inferior.

What i am speculating are the avionics and radar. So far, i havent heard of them being tested. We can only have an informed discussion and comparisons once the avionics, radar and engines have matured.
 
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Good analysis mate.

I agree that PAKFA still has some way to go (especially the engines), but that doesnt mean it will come out inferior.

What i am speculating are the avionics and radar. So far, i havent heard of them being tested. We can only have an informed discussion and comparisons once the avionics, radar and engines have matured.

Not related to Pakfa avionics. However, the next two video's talk about Russia microprocessing technology.

I got these from another forum. They talk about 90nm microprocessing and soon to be 45nm microprocessing. At about the 9 second mark in the first video they show a microprocessor several times thiner than the human hair.



 
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Since the other discussion is closed, I will attempt to address some issues that I believe would be informative to interested readers.

We still dont know the design or the real capabilities of the engines which are to power the PAK-FA. That includes the shape of the exhaust nozzles. IIRC there was a Su-27/35 test bed with 2D TVC with nozzles like those of F-22. We dont know whether that would be incorporated into the new engines.

Another point that many missed here is the placement of the engines on PAK-FA. If you look closely the engines are aligned at an angle to the central axis with the nozzles pointing lightly outwards. Wrt the explanation that you gave regarding wide placement of engines and their effect on flight control, what do you think about this development? Sukhoi engineers probably had a very good reason to design the placement of eninges in that particular manner.

http://www.defence.pk/forums/650027-post1257.html
He just described the underpowered engines without TVC used in test flights. I am asking about the actual engines that are developed but not yet integrated.
Brief explanation on engine location...

Aerospace/Aviation: Aircraft Structure (Jet Engine's Location), fusilage, single prop
Prime consideration is keeping the top of the wing clean for better lift. Placing the engine on top of the wing would put the thrust above the center line of the aircraft.
Having the thrust below the center line is a compromise.
That's why some aircraft have the engines mounted on the side of the fusilage at the center line. This also aids in relieving in yaw in the event of an engine failure. Keeping thrust as close to the center line both vertically and horizontally makes for good design. Having thrust below the wing pushing up is better than having it above pushing down.
In single prop aircraft, engines were sometime angled down and to the right to offset torgue and produce better climbing angles. Propjet aircraft had engines mounted on top of the wings for prop ground clearance. Again another compromise in design. Any structural advantage would be the ability to drop an engine if the structure failed rather than to have it break into the wing or tail section.
First consideration is the lifting fuselage design. Some may called this 'blended wing body' (BWB) design. The B-2 is blended body. The F-14, F-15, F-16 and F-18 are lifting fuselage. So are top MIG and Sukhoi fighters. Next consideration is internal volume usage, as in how does the designer intend to use the fuselage. Fuel is a diminishing mass, not only that, under maneuvers, liquids moving inside a container create negative force influence on the body. Where to run all the wirings and mechanical contraptions necessary for flight?

Next consideration is physics. The further a mass is from the center of gravity, the greater the rotational kinetic energy required to change the body's state of motion. This requirement is applicable in both initiating a maneuver and stopping the maneuver. Take a simple aileron roll, for example, of an aircraft with two underwing engine pods. Because these two masses are noticeably far apart from the fuselage, it will require higher aileron deflection angle and higher aileron deflection rate to initiate a roll maneuver than if the two engines are closer to the fuselage. Once the aircraft is in this roll, it will have a higher roll rate, hence possibly greater maneuverability. The downside is that it will require greater aileron force to stop the roll, as in -- both initiating a maneuver and stopping the maneuver. In basic fighter maneuver (BFM) a pilot would be rolling in one direction in very short time before changing to the opposite roll direction, so mass centralization is a positive.

Here is an established example...

Lockheed 322-15/P-38F
The P38 truly shines at high altitudes, where other airplanes start gasping for air. Due to it's long wingspan and high rotational inertia resulting from putting engines out on nacelles, it's roll performance is poor until you get to higher altitudes and higher true airspeeds. Unfortunately, except for hunting strategic bombers or escorting your own bombers, WW2OL air combat takes place down at low altitudes, where the thicker air works against the P38. Even the boosted ailerons that came later in the war didn't help the roll rate below 440kph IAS.
Boosted ailerons means higher aileron deflection angle and higher aileron deflection rate as stated above. For the P-38, each wing contain a supercharged V-12 engine. No wonder powered ailerons did not help the aircraft much.

The Flankedsteak...errr...I mean...Flanker...series has wingspan of 14.7 meters or slightly above 15 meters. So far the PAK-FA's wingspan is little different. The Raptor's wingspan is about 13.5 meters. There are more to wing designs than just wingspan dimensions but it is telling of Sukhoi's consistency across its product line that goes beyond similarity in appearance, which is undeniable. From what is available so far, the PAK-FA's engines are further apart from each other than the Flanker series engines. All these factors must be in fine balance with each other and why decimal points exists in these physical dimensions. Sukhoi must be very comfortable with the basic design of the original Flanker to carry so much of it forward to the PAK-FA.

Now on thrust vectoring (TV) and how it relate to a flight control system (FLCS), specifically -- flight control laws (FCL).

Flight control laws (FCL) are finalized through five distinct phases:

- Off-line design. This is where the basic principles of flight theories are laid out. System architecture variations must be defined. A glider have no need for pneudraulics but a fighter would. Air data requirements specified -- extract only the information necessary for the functioning of the system architecture. The variations list is considerable. The Space Shuttle's FCL? We are talking about a vehicle that changes environment, going from one that give air data to one that does not. Gravity does have an effect on gyroscopes. This vehicle goes from a gravity environment to one that effectively has none. Everything at this stage is simulated.

- Pilot-in-the-loop. Also simulated and self-explanatory. This phase simulate the system's responses to pilot inputs, which contain both predictable to unpredictable commands.

User Stories - Gulfstream Aerospace Develops Pilot-in-the-Loop Aircraft Simulator with MathWorks Tools
Gulfstream engineers needed to build a flexible pilot-in-the-loop aircraft simulation facility, including a six-degrees-of-freedom simulation of the aircraft, in preparation for a scheduled flight test of a modified Gulfstream G550.

- Iron bird. This phase actually insert the flight control system (FLCS) hardware into the so far theorized system architecture. The FCL for a delta winged aircraft do not have horizontal rear stabilators in its equations, for example.

Aerospace Test Systems - Iron Bird Full Scale Testing | Moog
Iron bird solutions can be used to study and test flight controls, landing gears, and hydraulics of an aircraft system. Both the correct functioning of different aircraft systems, as well as endurance testing can be supported.

- Clearance. This phase is where the entire FCL, from theory to hardware integration, is demonstrated to be functional, at least within certainty limits, such as those coming from virtual air data inputs, in other words, we are giving the FCL a range of crosswind wind speed, for example, and demonstrate how the FCL can compensate the aircraft in that situation.

- Flight test. Self-explanatory. Regarding the crosswind example from above, the flight test is where we will experience the greater range of environmental spectrum.

The advent of FCL enable us to study closely stages of flight with the environmental conditions and pilot inputs within each stage. Take-offs and Landings do have variations in environmental inputs they are far narrower in range. Barometric pressure, for example, do not varies much from ground level to several hundreds meters altitude. Same for pilot inputs. Barring collision avoidance or engine out compensatory maneuvers, pilot commands variations are also narrow in range. The more we know about these variations and their ranges inside each stage of flight, from source to destination, the better we can incorporate their automation into FCL and naturally reduces pilot workload.

But here is the complication...And we will take mass loss, for example...

Military aircrafts, from fighters to transports, but especially fighters, can have large variations of mass, center of gravity and inertia. Transports usually behave the same as airliners. On the other hand, a fighter-bomber may approach a runway as if he is going to land, except that his speed is far higher than normal, and in a few seconds, his mass is considerably lighter, aka 'bomb delivery'. The FCL for fighters must be able to compensate for these great variations in environmental and pilot inputs. Not only are they great but can also be sudden as in a bomb delivery. If an airliner do experience as great and as sudden a loss of mass of several thousands kilos, it would be considered catastrophic. For a bomber or fighter-bomber, such a loss would be considered routine. The Clearance phase is where the FCL must demonstrate adequate ability to cope with such a great loss of mass, changes to center of gravity and inertia. What if a bomb or missile failed to leave its rack, aka 'hung ordnance'? Indeed such a situation would create an off-balanced center of gravity and possibly off-center aerodynamic drag. The FCL must be able to adjust the entire FLCS to compensate for this abnormal condition, probably until the aircraft made it home.

The higher the performance envelope, the greater the complexity level of the FCL for a particular design. Relaxed stability is a requirement these days for fighters. The problem for the Clearance phase is that even now we are unable to anticipate the effects of the full environmental spectrum, from air data to aerodynamics, upon current known aircraft designs with relaxed stability. Once we input what we know, depending on the computational power available to us, of course, the Clearance result will give us Flight test conditions. This is why we see flight tests where the aircraft just make a go-around and land and he did with full gear down. The next test will have gear up, but still just a go-around and land. The next test may have the pilot do a few aileron rolls and land. And so on. The data collected in each test flight in the Flight test phase is analyzed and compared against the Clearance theoretical result that allowed that particular test flight. There would be adjustments in Clearance to create new Flight test and each adjustment remove some restrictions. Hopefully the entire project is approved for acceptance by the customer, be it Delta Airlines or the USAF. So it is imperative that as much of work should be done and be successful in Clearance as possible. More adjustments mean more test flights and that drive up cost -- in time and patience.

2nd Workshop on Clearance of Flight Control Laws
This workshop is organized within the activites of the EC STREP-project COFCLUO (Clearance Of Flight Control Laws Using Optimisation) and is intended to bring together researchers and practitioners with interest in the variety of problems and techniques related to the clearance of flight control laws. A first successful workshop was already held in Siena in 2008. We expect that this second workshop will delineate the state-of-the-art and will cover emerging trends in this research area. The program will include overview presentations of invited speakers illustrating their research activity, as well as talks on the achievements of the COFCLUO project, which at the time of the conference will be terminated.
This is serious business when an international workshop is created just for the purpose of theorizing something as esoteric as 'flight control laws'. How recent is this workshop indicate that computational power is still inadequate at the Clearance phase, hence we still need test flights. It also hint at the computational power required to create something as exotic as the F-22 or the B-2, as far as avionics goes. The Clearance phase is an extremely time, money and patience consuming effort.

According to US sources, the F-22's FLCS, or FCL, have automatic controls of the aircraft's thrust vectoring system...

How Things Work: Thrust Vectoring | Flight Today | Air & Space Magazine
They simply point the airplane where they want, and the onboard systems automatically coordinate the right combination of flaps, rudder, elevator, and nozzle angle. "The F119's vectoring nozzle is integrated into the F-22 flight control system" so that "the pilot doesn't control the nozzle independently," says Chris Flynn, Pratt & Whitney's F119 director.
When the US modified existing F-16 and F-18 to have TV capability, each aircraft's FCL were rewritten from the Off-line design phase. We are introducing an alternate avenue of changing the aircraft's attitude and one that we want to exclude from pilot's control. The word here is 'exclude' meaning the pilot never had control in the first place. To 'remove' mean the pilot did have control and now we are denying him that control. The FCL that contain both exclusion and removal of control from the pilot will be more complex than one that only 'exclude'. The reason is that even though the FLCS is currently allowing the pilot controls of the nozzles, it still must maintain vigilance of nozzle movements under all flight atttitude and conditions so that the system can smoothly reassert its own controls whenever the pilot decide to relinquish controls. In other words, there is no 'neutral' status for nozzle controls. There is 'neutral position' when the nozzles are in alignment with the aircraft but that position is still under control by someone.

Just as current high performance aircraft cannot fly without computer assist, I doubt that the Russians would have the PAK-FA's flight control laws (FCL) allow independent pilot nozzle control provision. Here is why...And we will revisit the in-flight emergency (IFE) of UA 232...

Propulsion Control of Airplanes
In July 1989, the tail engine of the DC-10 of United Airlines Flight 232, enroute from Denver to Minneapolis, sustained a "catastrophic uncontained failure" that created a hail of shrapnel, slicing the hydraulics lines of all three independent systems, leaving the aircraft "marginally controllable" at 37,000 feet. Contrary to the realistically motivated consensus at that time that this flight should have ended in disaster, Captain Al Haynes, with the help of United Captain and DC-10 Flight Instructor Dennis Fitch, quickly improvised a way to keep control of the aircraft by maneuvering the throttles of the remaining wing engines. To the great amazement of aviation officials, the crew managed to bring the aircraft to a crash landing in Sioux City, Iowa, saving the lifes of most of those on board.
EVERYTHING the aircrew did that day to land that aircraft constitute a set of flight control laws (FCL). It is irrelevant if those actions are mathematically recorded or not. Each action working either independently or in concert with other actions in response to aerodynamic forces and air data inputs violated no laws of physics. What we may called 'miraculous' is simply our emotional response based upon our inexperience and ignorance of aviation, airmanship and awe of someone's abilities in an extreme situation. Test pilots are very much like UA 232's crew in that test pilots stored within their minds, their muscle memory and their instincts a great deal of knowledge, conscious and subconscious, of many sets of FCLs. In an extreme situation, the test pilot will put together a superset of FCL comprised of many subsets of FCLs to try to recover the experimental aircraft. The human mind remains supreme in this ability despite our accomplishments in computer science. Once the emergency is over, the superset of FCL that allowed the recovery -- !?!? poof !?!?. We are left with the human and hopefully we can mathematically quantify some of his techniques into something more concrete.

Thrust vectoring (TV) is no different than UA 232's selective asymmetric thrust in that we are introducing a new influence into the current basic FCL. The difference here is that UA 232's asymmetric thrust is ad-hoc while TV is deliberate. UA 232's asymmetric thrust was working pretty much alone since the FLCS was barely available. But we demanding that TV works in concert with a fully functional FLCS in an aircraft that will go to extreme maneuvers. In effect, by allowing the pilot independent control of TV nozzles we are asking for a test pilot in every PAK-FA fighter. The US is not making that request. Good luck to the Russians and the Indians. Yer gonna need it.

I may have poke fun at the Russians but am also willing to give them much leeway with the PAK-FA at this time. Keep in mind that this is the first test flight under the 5 phases of FCL development explained above. The next Clearance will have greater allowance for the next Flight test. If the Russians do decide to make hardware changes they may have to go back as far as the Iron bird phase and move forward again. This is the reason why it is an extreme rarity that any aircraft, civilian or military, have the latest and greatest technology. The further the regression, the more time, money and patience it will cost. This is why that there is a good probability that what we see here today will be very similar to the final product given the delays the PAK-FA project have experienced so far. The engineer must obey the laws of physics. The project manager must obey the laws of economics. The manager can have parallel FCL developments with different hardwares but when everything is totaled, the manpower hours will still tell the same tale -- that the more complex the design, the more complext the FCL, so the more money it will cost.

Finally...This is also why every indigenous aviation program should be applauded. I chuckled every time I read someone spout 'reverse engineer' a bought aircraft. A modern high performance aircraft can have its hardware reverse engineered. But without sufficiently complex FCLs to manage the hardware, all you will have are expensive and pretty looking static displays as the FCL codes are quite closed source. There must be complete mastery of the five phases of FCL development. Else all you can achieve are WW II level fighters. Can Russia fully 'reverse engineer' an F-22 in all aspects? Yes. Can China? May be. Can Japan? Better odds than China. Can South Korea? Same as China. Can India or Pakistan or Iran? Sorry. Hope none will take offense. The Iranians cannot even reproduce an F-14. Once a country is determined to have an indigenous aviation program, there should not be any pauses. The collapse of the Soviet Union was disastrous for Russian aviation, hence so much attention and hopes are upon the PAK-FA.
 
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http://www.defence.pk/forums/650327-post1293.html
point taken but its condradictory to what you say - size has nothing to do with the stealthiness of the plane - exclude that then yes probably - but then again - the original F-15 is smaller than the SU-27/30 yet has a bigger RCS at 25m2 a diff of 5m2. so again size can make a difference but then again can you exlain the conundrum here??
Whoopsss...Size does matter, and ladies, admit it, you check out our 'packages' just as much as we check out yours. But let us get back to aviation. Size does matter in radar reflectivity -- obliquely, anyway. We should not mix up measured dimensions, aka 'size', with SURFACE AREA, particularly the side of the body that faces the seeking radar. Also, if the aircraft has a lot of surface features, such as bumps and protruding antennas, those will increase the total surface area without affecting measured dimensions.

1b0a2bfe33fa269659383cd778f1e0aa.jpg


The larger the surface area, or more precisely a continuous expanse of surface are that are free of protrusions, the greater the difficulty it will be to reduce the aircraft's overall radar reflectivity, hence the technique illustrated above. I can take the total surface area of the B-2, bunch it up into a shape whose final measured dimensions will be smaller but whose radar reflectivity will turn this new thing into an electronic beacon. All that surface area has to go somewhere so where else but into protrusions and corners. So in away size have nothing directly to RCS but larger size equal to more surface area and I have to deal with that somehow.
 
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http://www.defence.pk/forums/650327-post1293.html

Whoopsss...Size does matter, and ladies, admit it, you check out our 'packages' just as much as we check out yours. But let us get back to aviation. Size does matter in radar reflectivity -- obliquely, anyway. We should not mix up measured dimensions, aka 'size', with SURFACE AREA, particularly the side of the body that faces the seeking radar. Also, if the aircraft has a lot of surface features, such as bumps and protruding antennas, those will increase the total surface area without affecting measured dimensions.

1b0a2bfe33fa269659383cd778f1e0aa.jpg


The larger the surface area, or more precisely a continuous expanse of surface are that are free of protrusions, the greater the difficulty it will be to reduce the aircraft's overall radar reflectivity, hence the technique illustrated above. I can take the total surface area of the B-2, bunch it up into a shape whose final measured dimensions will be smaller but whose radar reflectivity will turn this new thing into an electronic beacon. All that surface area has to go somewhere so where else but into protrusions and corners. So in away size have nothing directly to RCS but larger size equal to more surface area and I have to deal with that somehow.

GAMBIT - Thanks for the post mate - really informative - I understand the concept of surface area and reflection - I posed that question to Growler to make him understand that you cannot separate stealth from the airplane which has been designed to be STEALTH - Was a question for him to stop the unnecessary bashing of PAK-FA!

I am also not sure but EMO girl posted a link in the previous thread that mentions the RCS of F-18 SH to be around .75m2 and that of the Rafale and EF to be somewhere between .25 and .75 - I doubt that to be the case as BAE or Boeing or Dassault have not clearly confirmed on the RCS. Any thoughts on it?
 
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F-22 Raptor Materials and Processes

Validating structural materials is especially important to the F-22 because new material technologies were incorporated to maximize aircraft performance. The overall percentage of composites in the F-22 (approximately 25%) is historically high, though not unprecedented. However, the extensive application of Resin Transfer Molding (RTM) technology and high temperature bismaleimide (BMI) composite materials directly resulted in the high weight/performance efficiency the Raptor demonstrates. The use of metallics technologies such as titanium Hot Isostatic Pressed (HIP) castings and electron beam welding allowed the airframe designers to incorporate complex features into a single component without the weight of fastened assemblies. The continuing challenge is to reduce material and component costs through a constant reassessment of emerging technologies. Recently developed machining technologies, for instance, have allowed the inlet canted frame lip to be changed from a casting to a lower cost machined component with no appreciable weight penalty.

Traditional aircraft materials such as aluminum and steel make up about 1/5 of the F-22's structure by weight. The high performance capabilities of the F-22 requires the significant use of titanium (42 % of all structural materials by weight) and composite materials (24 % by weight), which are both stronger and lighter weight than traditional materials, and offer better protection against corrosion. Titanium also offers higher temperature resistance.

Airframe Structural Materials By Weight.

(Current F-22 Weight Distribution)



Titanium 64 (Ti-64) 36%
Thermoset Composites 24%
Aluminum (Al) 16%
Other Materials* 15%
Steel 6%
Titanium 62222 (Ti-62222) 3%
Thermoplastic Composites >1%
* Other materials include coatings, paint, transparency, integrated forebody (radome), tires, brakes, sealants, adhesives, seals, actuators, gases, and fluids.

The types of titanium are different alloys and have different applications on the F-22. Ti-62222 is a very high-strength alloy that was introduced on the F-22.

On the F-22, the number of parts made from thermoset composites is approximately a 50/50 split between epoxy resin parts and bismaleimide (BMI) parts. The aircraft's exterior skins are all BMI, which offer high strength and high temperature resistance.

Thermoplastic composites are also highly durable materials but, unlike thermosets, thermoplastics can be reheated and re-formed. Thermoplastics proved more expensive and more difficult to incorporate in the F-22 than had been hoped in the early days of the program.

Thermoplastics are being used on the F-22 for items such as landing gear and weapons bay doors (which are opened frequently), where impact damage tolerance (to things such as small rocks that are kicked up from the runway, etc.) is required.

The Airmet 100 steel alloy used in the F-22's main landing gear is another innovation. It is one of the first applications of a special heat treatment of steel, which provides greater corrosion protection to the main gear piston axle.

Hot Isostatic Pressing (HIP) Casting

Hot Isostatic Pressing (HIP) casting is a process where metallic castings are subjected to very high temperatures in a static pressure environment (more than 10,000 pounds per square inch). The effect is to collapse, or "heal", voids (gas pockets) that otherwise may be present. On the F-22, structural titanium castings are HIP'ed to eliminate any voids that are present from the casting process.

HIP casting is used on six large structures on the F-22: the rudder actuator housing (one for each rudder), the canopy deck, the wing side-of-body (SOB) forward and aft fittings (four total, two for each wing), the aileron strongback (one for each aileron, two total), and the inlet canted frame (one each for the left and right inlets).

Resin Transfer Molding (RTM)

Resin Transfer Molding (RTM)

The F-22 is the first aircraft to take advantage of Resin Transfer Molding (RTM) of composite parts. RTM is a method of composite parts fabrication well suited to economically fabricating complex shaped details repeatedly to tight dimensional tolerances.

Large composite parts traditionally are formed by applying and pressurizing hundreds of layers of fabric that contain a pre-embedded resin, and curing, or 'baking,' them in an autoclave. This is a very time consuming and labor intensive process.

The process employs fibrous "preforms" that are formed under vacuum from stacks of fabric and placed in metal tooling that matches the shape of the part. The tool is then injected with heated resin under pressure. The benefit of the matched metal tooling to RTM is a high level of part reproducibility, consistency in assembly operations, and consequently, economies of scale.

RTM is used to fabricate more than 400 parts for the F-22's structure ranging from inlet lip edges to load-bearing sine-wave spars in the fighter's wings. At Boeing, RTM has reduced the cost of wing spars by 20 percent and has cut in half the number of reinforcement parts needed for installing the spars in the wings. Both BMI and epoxy parts are fabricated using RTM.

Composite Pivot Shaft (CPS)

The composite pivot shaft is an application of Automated Fiber Placement (AFP) technology, employed with unique tooling approaches to incorporate a composite structure in place of a titanium one in a flight-critical application - the F-22's horizontal stabilizers.

AFP technology makes possible the exact fiber positioning required to achieve the complex geometry of the pivot shaft, which is a 10-inch diameter cylinder at one end; and a rectangular spar at the other approximately four inches wide; with a offset in the transition area. Its shape can be likened to that of an oversized hockey stick.

Alliant Techsystems is the contractor for the composite pivot shaft, which is laid out using computerized fiber placement machines. The pivot shaft is composed of more than 400 plys (layers) of composite tow tapes ranging from 1/8 of an inch wide to 1/2 inch wide.

The shaft is cured in stages to prevent internal cracking and no wrinkles, as there is no allowances for voids in the shaft. After layup, the shafts are nondestructively inspected and tested.

The composite pivot shafts take up to 60 days to produce, but they save 90 pounds per shipset (two shafts) over titanium, which is an extremely large amount of weight to take out of an aircraft at one time. Also, because of the high temperatures in the engine bay area of the fighter, it is constructed mostly of titanium, and any weight is difficult to engineer out of that area.

When the first F-22 was rolled out in April 1997, four shipsets of flightworthy composite pivot shafts had already been produced. A plan is in place to use thicker tow tapes, which should greatly reduce production time for the shafts.

Electron Beam (EB) Welding

An automated process called electron beam (EB) welding is helping Boeing and Aerojet, its supplier, build lighter-weight titanium assemblies for the aft fuselage. EB welding takes place in a vacuum chamber and uses a stream of electrons to weld titanium parts together.

Performing the welding in a vacuum prevents exposure to oxygen, which can create an undesirable brittle surface during the process. Electron beam welding is able to weld thick titanium parts (i.e., more than an inch) considerably better than other methods.

Electron beam welding reduces the need for fasteners in some fuselage components by up to 75%, which reduces weight, simplifies the assembly process, and avoids the costs associated with fasteners. The reduction in the number of fasteners also means fewer openings for possible fuel leaks.

F-22 Materials and Processes
 
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Another point: Has anyone noticed the pictures available on the net - Look at the belly - This is the Photoshop image of the plane we saw flying the other day

http://attach.high-g.net/attachments/pak_fa_render2_562.jpg

This is the actual prototype:

http://i518.photobucket.com/albums/u349/antiindian/332.jpg?t=1265018711

if you focus on the middle area it seems there are differences - the photoshop version has a bump - where the weapons bay is housed - any possibility if these changes can be carried forward into the future prototypes??

:cheers:
 
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GAMBIT - Thanks for the post mate - really informative - I understand the concept of surface area and reflection - I posed that question to Growler to make him understand that you cannot separate stealth from the airplane which has been designed to be STEALTH - Was a question for him to stop the unnecessary bashing of PAK-FA!

I am also not sure but EMO girl posted a link in the previous thread that mentions the RCS of F-18 SH to be around .75m2 and that of the Rafale and EF to be somewhere between .25 and .75 - I doubt that to be the case as BAE or Boeing or Dassault have not clearly confirmed on the RCS. Any thoughts on it?

there is NO OFFICIAL value of RCS by Dassault & others
its all the predicted RCS

as for how Rafale has such a reduced RCS & IR signature, its a combination of many things
i tried to explain some in that thread...
http://www.defence.pk/forums/650413-post1315.html

the whole theory of Rafale is just three points

The Rafale is designed to meet the following requirements :
  • stealth characteristics,
  • interoperability with NATO air forces,
  • optimization of man-machine interface,
  • global control of development and operating costs.
LINK Rafale C
 
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Another point: Has anyone noticed the pictures available on the net - Look at the belly - This is the Photoshop image of the plane we saw flying the other day

http://attach.high-g.net/attachments/pak_fa_render2_562.jpg

This is the actual prototype:

http://i518.photobucket.com/albums/u349/antiindian/332.jpg?t=1265018711

if you focus on the middle area it seems there are differences - the photoshop version has a bump - where the weapons bay is housed - any possibility if these changes can be carried forward into the future prototypes??

:cheers:
I posted this on the original Pak Fa thread before, it also shows the 2 arrays to the side of the cockpit and additional arrays in the flaps:
79d405d6cb291811d074ea5760d8b272.jpg

The L Band arrays in the flaps are already integrated in some flankers, but no doubt it would be an advantage if such a big area can be scaned by its radar.
Here some more infos about it:

Assessing the Tikhomirov NIIP L-Band Active Electronically Steered Array

Btw, though the parachute is integrated in the tail sting, I have some doubts that there will be space or another radar array.
 
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