^ well if we are posting fan art..
some one made a CG based on that partial model on the desk above
^ well if we are posting fan art..
some one made a CG based on that partial model on the desk above
That is model I did years ago, so it is the Russians that copied me xD
Early version of the plane in my avatar
I am sure there will be a single-engine fighter with an engine izd.30. Probably in two variants, horizontal take-off and landing and short take-off and vertical landing for aircraft carrier and universal landing craft
^ wouldnt the fan right next to the intake create some problems with the air?
@LMFS : (I have read you enough to know that you might not have been in your better day writing the above. Hence I know you won't boil-off upon reading the following joke
My much needed input for your design:
Hello, did you all wondering about it miss the info that MiG has recently been basically incorporated into Sukhoi, so there will be no more competition between these two, but instead Sukhoi has an access to all MiG's developments, including those concerning new generation single engine fighter projects (which are independent from MiG-29 family, by the way)? Similar situation as to Kamov-Mil, really; on paper it's a merger, but in reality of course the more dominant partner prevails (not unsimilar to Boeing-McDonnell Douglas merger).Here a bit more realistic...
But now built by Silhouette?? I thought it is a MiG project? ... and any idea how it will be presented at MAKS?
The second red equation tells us that thrust when sourced from a static volume of air depends on the speed difference b/w the air at the inlet and exhaust sections.
If two engines (fan and Propulsion) in gets air from the same area (the dorsal inlet you mentions suck air coming roughly from the same area your fan tries to get it), the air at both propulsion devices inlets would be more accelerated than if both devices were widely separated (it's the ventury effect applied to the volume of air above the airframe).
Hence the loss in thrust.
Moreover, the first red equation tells us that the diffencial pressure b/w the inlet and outlet increases the thrust when positive and decrease it it when negative (reverse thrust - theorical case). If you ingest the air from another engine, that difference will be at best minimal what will results in a loss of thrust.
Engine can even stall in such case (remember Topgun sequence when mavericks Tomcat loose an engine while crossing the exhausts trail of his leader).
In the design above the dorsal intake is not represented, but since the lifting fan is much more forward placed and the main engine much more to the rear than in the F-35B, both inlets could be many times further apart. But in any case, you cannot drain the atmosphere through an inlet (Venturi does not apply on open air but to the airflow inside a pipe section) so that the close proximity of both inlets in the F-35B is inconsecuential in that regard.Well you can see that there is quite a separation b/w the fan inlet and the auxiliary one for the main engine.
I don't think so Tomcat. Both intakes have an unrestricted airflow and negligible mutual influence.Since there is an increased velocity from the Air at rest and that at the inlet section, the stream tube is contracted and you can generally says that you have what looks like a venturi. Hence the mention here.
Just to make sure, another drawing (sorry again for the hack) to show roughly the position of the different doors for the vertical lift: top cover for the lifting fan, lower cover of the lifting fan with additional mission of shielding the main intake / channelling the airflow from the fan clear of the airframe and doors for the dorsal intake. You see the situation is much better than in F-35B, which actually works based on the same principle, with dorsal intake and fan much further apart. The necessary thrust relation in hover between main nozzle and fan is ca. 2/3 and 1/3 (because the fan is much further from the CoG) so the fan can be smaller and the shaft lighter/longer than in F-35B. Only drawback is that this layout is not compatible with a manned plane.But then @LMFS I don't see how you can't figure that two engines sucking the same air will accelerate that air faster than one of them.
I think I have seen something like that recently, but please post it. Actually I think it is more likely that the plane does not have canards, mine is a pretty radical layout, and today canards are not so advantageous as some years ago since planes with reduced or negative stability actually get lift and not downforce from conventional tail surfaces. The idea behind this rather exotic layout is to have a triplane MFI-like configuration, which is the best for trimming, maximize the integral aerodynamic layout gains (blended wing body) and have powerful lift augmentation with the canards. A conventional layout is perfectly possible too, and probably less risky. The canted YF-23 tails make sense too, they would save weight though I have not seen Russia experiment with that much.I had drawn an airplane similar to yours but without the canards and the tail surfaces more angled like the yf-23. I'm not an aerospace engineer but I used to build RC airplanes, maybe I'll upload my take on the subject later! I feel that if the Russians are going for the light fighter they are going to make hard decisions. Do they pursue an aircraft capable of operating from a carrier? with the potential of selling it to the Indians? or that ship already sailed for them? If they go for a fighter easy to convert to naval operations I don't see them using only one engine. If they go that route they risk creating a mig-29 2.0 that doesn't seem to offer enough savings to compete with the flanker family. If they go single engine they need to make a mig-21 2.0 so they can be successful selling them. It seems hard to think that they will make something like the f-35.
The problem is that, if you are to use a single Izd. 30 for your fighter, the size of the engine cannot be that small in proportion to the airframe, unless you have a very short afterburner section, which here screws up all the prerequisite for your design. In reality it would span from where the blue line is, potentially even further up front.
The shaft is long and that is one of the technical issues that would need to be checked, of course. But since the amount of power to handle is way smaller than in F-35 (1/3 of total lift instead of 1/2), the solution already works in that plane (shorter shaft I know) and given the many advantages, I think it is at least an option worth considering.I think it would be wiser to bring the lift fan a bit closer to the engine since that shaft that connects the two seems extremely long and as an engineer, I wouldn't want to deal with that kind of thing for an aircraft
Yes of course, but the share of the lifting fan is reduced and that is precisely the goal. You cannot extract as much power from the turbine as you want and keep the engine operating effectively as a jet, there are also limits for the shaft and size of the lifting fan. By the way Lockheed crammed the lifting fan into the cockpit and by the very forward position of the main engine you can see they reached the practical limits of the design with a share of lift close to 50:50 and bays parallel to the engine. The price to pay is a terrible supersonic drag.Also I think you're idea is concerning the pitching moment of the engine in relation to the lift fan but I should tell you that the CoG has not much to do with the total mass of the aircraft, which in case of VTOL operation means that you would still need the same amount of combined thrust to lift the aircraft as to if you have the lift fan closer to the CoG.
Yes if you use HW for generating lifting fan you need to remove something else, that is something that needs to be accepted the moment a STOVL plane is developed. In this case you have the space that normally would be used by the pilot gone, but the avionics bay at the nose and after the pilot are almost intact, as well as the fuel tanks and the weapon bays, which are far more important. The radar here is limited by the aperture more than anything else.Also you could potentially use the space where you positioned the lift fan for avionics to support bigger radar.
The internal volume lost in a long air duct is a better compromise than increased drag because there is no place for the weapon bays in line with the engine. Side intakes with S duct and confluence in front of the engine mean the central section of the plane cannot be used for the weapon bays or if you do it, you get swallow bays like in F-22. So you would get more drag and weight having to move the bays to the sides of the engine or losing the ability to carry big A2G weapons. The original design of this plane is CTOL and the whole idea of the sketch above is to get a STOVL layout without affecting the performance of the more numerous and more critical CTOL one, contrary to what happened with the F-35. Ventral intake for a single engine is simpler, lighter and less draggy, and IMHO it allows to accommodate the weapon bays, since the air duct does not need to be perfectly straight, unlike the engine or the weapons.That's a lot of space wasted, ie it's better off means no ventral VTOL intake.
This is how it works in the F-35 so I see no airflow problem. Eventually the doors of the dorsal intake could be substituted with a single door inclined forward, helping capture more air when the plane starts moving forward, like that at the lifting fan of the F-35.I see that for that reason you have place the secondary intake closer to the engine far behind the primary intake, but that would cause another air flow problem.
See the discussion above, the main intake would be shielded from the flow of the lifting fan, since there is an alternative air intake the main one can be closed, and the very shape of the lower door roughly at the DSI bump can be used for that. Some planes take off with closed main intakes, like the Yak-130 and old MiG-29. The main problem I would see otherwise is not the lack of airflow to the main engine but rather the fan airflow being sucked into the intake, reducing lift because the air would interact with the airframe instead of transferring moment to the surroundings and eventually to the ground. Therefore the convenience to steer it past the intake.This also means that you would need to use you conventional intake for both the VTOL and horizontal flight operations, which means that the lift fan position is very problematic in terms of air flow, since it will drag the air near the jet stream with it, meaning substantial drop-off of airflow to the engine itself.
Due to the separation between the intake and the nozzle, the fact that the air from the fan is already screening the exhaust air from reaching the main intake, the existence of the roll posts and the presence of the dorsal intake, I don't see that as a big problem. It is much more critical that the forward lifting device in this case is a fan and not an engine, because that air is much more prone to be ingested by the intakes, which are also forward placed.Also, in such case where you need to use the same intake for VTOL and normal flight profiles, there's another reason you would like to have your lift fan closer to you engine, which is the screening effect of the exhaust gas from the engine nozzle. Harrier's forward nozzle was bypass-air-only and the X-32 had a separate screening device which bled the air from the engine. F-35's lift fan serves the same function as well, although its importance is lower since there's a separate intake on the ventral surface. These kind of screening device, either augmental like the X-32 or thrust related like the harrier, should be placed in between the intake and the engine itself, which is not the case in your
Thanks for the reasoned criticism!My 5 cents.
Sorry LMFS, while you were writing your reply I had to edit my own post because I've found out that my own prerequisite, embarrassingly, was wrong! I wonder what's your take about my new comment on the design(about the aircraft proportion)? I see that some of your points apply regardless, like you take about the dorsal aux. intake. Regardless, thank you for the explanation.The shaft is long and that is one of the technical issues that would need to be checked, of course. But since the amount of power to handle is way smaller than in F-35 (1/3 of total lift instead of 1/2), the solution already works in that plane (shorter shaft I know) and given the many advantages, I think it is at least an option worth considering.I think it would be wiser to bring the lift fan a bit closer to the engine since that shaft that connects the two seems extremely long and as an engineer, I wouldn't want to deal with that kind of thing for an aircraft
The whole idea of the design is precisely to have the lifting fan and the main engine far apart, so that the weapons can be carried in line with the engine in the middle section of the plane and not at the sides like in the F-35. That is a terrible solution for the aero and general layout of the plane. [...]
Thanks for the reasoned criticism!My 5 cents.
I should question that a bit, since the problem with the F-35 being that thick was to have a 2,000 lbs JDAM internally + large amount of fuel, which are all mounted on the upper half of the fuselage. As long as you have your inlet duct spanning through, your IWB will need to be placed on the side of the inlet duct regardless of the lift fan position, unless you are okay with either less fuel or/and less internal weapons payload wouldn't it? I guess you are thinking about an inlet duct that goes over the IWB but that would be where large part of the fuel tanks are for the F-35. Well at least that solves the problem of dorsal aux. duct taking up too much space, as it would be reasonably close to the inlet duct.The whole idea of the design is precisely to have the lifting fan and the main engine far apart, so that the weapons can be carried in line with the engine in the middle section of the plane and not at the sides like in the F-35. That is a terrible solution for the aero and general layout of the plane.
No problem, publishing the idea means opening it to criticism. Thanks for being constructiveWait, maybe even my edited comment is false as well. If we consider the Izd. 30 to be somewhere in the region of the 5m length, that model hasn't got much problem. I guess I messed up? My apologies LMFS. I guess there were some visual deception due to the size and position of the wings I guess.
The problem of the F-35 IMHO is not the size of the JDAMs per se, is the fact that they placed those big bays in parallel with the engine. What I consider a good fighter design takes the unavoidable sources of cross sectional area (engine and cockpit mainly) and wraps all the rest of the elements as tight as possible within that footprint. That means, in a single engine plane, to place the IWB in line with the engine and not in parallel. For instance, F-16 is a little more than 4 sqm across, while F-35 is more than 8 sqm.I should question that a bit, since the problem with the F-35 being that thick was to have a 2,000 lbs JDAM internally + large amount of fuel, which are all mounted on the upper half of the fuselage. As long as you have your inlet duct spanning through, your IWB will need to be placed on the side of the inlet duct regardless of the lift fan position, unless you are okay with either less fuel or/and less internal weapons payload wouldn't it? I guess you are thinking about an inlet duct that goes over the IWB but that would be where large part of the fuel tanks are for the F-35. Well at least that solves the problem of dorsal aux. duct taking up too much space, as it would be reasonably close to the inlet duct.
Well if the lifting fan uses up the space of the cockpit there is no fuel advantage over the manned version and probably a certain loss compared to the unmanned CTOL one. STOVL normally destroys the layout of a plane, as well as its weight, payload and fuel capacity, so this is not so bad I think. Some additional doors, roll posts, some loss in the dorsal tanks because of the intake there, but very limited IMHO. I post some drawings to better understand the layout. The dorsal intake would be very close to the engine compressor, where the tank is most swallow.Maybe there could be some compensation for the fuel tank compartment since there is no cockpit? I guess that way it might be able to have as much fuel + s duct over the weapons bay that could house 2 2,000 lbs JDAM.