Sukhoi Su-30 MKI - Purpose of Thrust Vectoring
91Hub question: What is the purpose of Thrust Vectoring Nozzle in Sukhoi SU-30 MKI? I read this on some site and interested in more details.
Hi friend. This is a really nice question for me to answer. The answer was too difficult so it took me 3 days to research to come to the whole conclusion. There are various websites on the net which have information related to the same and below is my input after going through the information available. I also contacted various students who are studying aeronautical engineering and pursuing a career in the same and I gathered the details from them also. Below are some of the most common questions about thrust vectoring control system.
What is thrust vectoring?
Thurst vectoring is one of the best feature in Sukhoi SU-30 MKI. The nozzle works such that we can direct the engine thrust in a desired direction, which enhances the maneuverability, and it is this reason due to which Su-30 can perform cobra maneuvers and which is quite beneficial during dogfight. India is the second country after Russia to have an aircraft in service with such thrust vectoring capability.
USA has TVC in F-22 , X-31 , AV-8B Harrier II
UK has EF 2000
Germany has EF 2000
The maximum tilt angle for the SU-30 is 32 degrees in horizontal and 15 degrees in vertical. Even Eurofighter Typhoon does not have thrust vectoring. There are two types of thrust vectoring systems, 2D and 3D. Read below for more details on them.
What is 2D and 3D thrust vectoring and what is the difference between them?
2D means directing the thrust in horizontal and vertical whereas 3D means directing the thrust in vertical, horizontal, and angular. In 2D, nozzles can be deflected in only one direction (either both vertical or horizontal) and in 3D case their has been not any correct information because a few days back I read an article which stated that 3D can be deflected in different planes and yesterday I read another article and it stated that nozzle of 3D can be deflected in opposite direction. So their is quite confusion about the working of 3D nozzle.
The most important aspect related to any moving machine/vehicle/aeroplane, etc. is the propulsion power/the type of propulsion, etc.
Aspects related to propulsion, etc. could be best studied when they are related to an aeroplane, especially due to the fact that there is ideally zero friction between the aeroplane and air/unlike the case in cars/bikes/ships, etc.
The concept of three dimensional vectoring can also be applied to a propellor based aircraft. The principles and the benefits will be good if not dramatic when compared to the jet/rocket power, etc. The earlier types of jet technology were purely axisymmetric and the thrust was on the lines of the axis of the jet engine.
The 2-dimensional thrust vector allows the propulsion to be deflected in two directions, up and down, or sideways, left or right.
3 dimensional thrust vector allows the propulsion to be deflected in all 4 directions, i.e., up and down and left and right. It is even possible to add roll control using differential ideology. Basically the propulsion of one jet is directed upwards while the other is directed downwards.
The 3 dimensional thrust vectors allow you to carry all types of complex maneuvers. You can very well say 3 dimensional thrust add 4 more controls to the aircraft. In the absence of 3 dimensional thrust the pilot had to depend heavily on the basic controls such as rudder/elevator/flap/airelon, etc. It is quite possible that some complex maneuvers can be carried out without using the basic controls at all. The response time is improved a lot by using such multi dimensional thrusts.
Now learn how the thrust-vectoring nozzle is controlled?
Presumably, the nozzle sense is controlled by the avionics inside it, right? But it is the pilot who is given a direct feed on the nozzle angle? Because maneuvers like the Pugachev's Cobra supermaneuvers are too complex to fathom.
Pugachev's Cobra or dynamic braking is a maneuver in which within 3-4 seconds, the nose of the aircraft is pulled up to high angles of attack (80°-110°) and then returned to normal horizontal flight. This causes intensive loss of airspeed. You can execute this maneuver from level flight at various altitudes and at indicated airspeeds of 350-450 kilometers per hour.
In level flight at the appropriate entry speed of 350 to 450 km/h, disable the AOA limiter. Execute the cobra by pulling the stick fully aft. As the nose reaches the vertical (pointed straight up) allow the stick to go to neutral and let the nose fall back down to level flight. Smoothly increase thrust towards the end of the maneuver. The AOA limiter will automatically re-engage after executing the cobra.
Two facts, which make thrust vectoring difficult for other planes
- The main difficulty is to design a nozzle bearing that can work smoothly at extremely high engine exhaust temperatures, basically a problem of finding the right material. The Russians are using some alloy for this and some advanced lubricant they invented.
- The second is a problem of flight control. Thrust vectoring changes the complete control law for your aircraft. As a simple example, one of the very difficult fields in aerospace is tethered vehicle flight dynamics because it involves an asymmetric thrust vector. Thrust vectoring is having that vector in your control law. This is the reason that Americans are behind the Russians and they want to integrate the TV into the flight computer, so that the pilot can still fly with a single joystick; however, the Russians who are more practical and generally just want results, have a separate control for controlling TV of the nozzle, and the pilot uses his own feel of the aircraft to fly and use the thrust vectoring appropriately.
India has manufactured AL-31 engines with TV nozzles under license at the Nasik plant (Hindustan Aeronautics Limited).
Which other aircrafts are using this facility?
1. Harrier 1 and 2.
- Yakovlev Yak-141 which is the first supersonic VTOL fighter (Vertical Take-Off and Landing).
- JSF which is a naval version still has some problems with the vertical take-off and landing thing out there, so the US engineers had to call on the Russian engineers from Yakovlev to help them fix this problem.
- V-22 Osprey with VTOL and STOL (short takeoff and landing).
If anyone thinks that helicopters are using thrust vectoring, then I am too sorry because they do not come under the category of fixed-wing aircraft, as they are rotary wing aircrafts. All VTOL fixed wing fighters though have TV, they are not using it to achieve higher maneuverability. They simply use to bypass the engine exhaust through another duct pointing downwards. The challenge there is to achieve stability because for thrust pointing directly downwards, there are a lot of stability issues which pop up, not to mention conditions when there is high wind or gusts in the atmosphere which is very common on a ship in the ocean, but the main challenge as I pointed earlier in fighters when they use TV for maneuverability is that then you have to move the nozzles itself and not just bypass the exhaust through a separate duct, so designing the bearing becomes a difficult issue.
I will come up with more advanced answers related to thrust vectoring nozzle and maneuvers which are possible by using this system in my upcoming hubs.
Take care. Happy flying...........
P.S.: As I promised, I have created a new hub which is the second part of this hub - Thrust vectoring Sukhoi Su-30 MKI Part II
In this new article, I have written on thrust vectoring success by American's on V-22 Osprey and compared it with Sukhoi MKi
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Yes this hub is meant for all but especially for students who are pursuing career in aviation, aeronautics, and aerodynamics. Thanks Pravin for visiting and taking time to read this useful hub.
A very interesting hub indeed. I am an aeronautics fan too. Thanks.
So quicksand you are also the one like me who have keen interest in aeronautics. We were not able to become an aeronautic engineer or a pilot but at least we can write and share our thoughts on this through hubpages which is a great platform for any type of topic you want to read, understand, write, think, and discuss about.
Thanks for this nice explanation. Another good article I read after a long time.
Thank you warplane lover for your visit and comment.
this is cool
i need some more infomation on the mechanism on 3-D vectoring
could you manage??????
very intrested
thinking it as a project
What do you want to know about 3-D vectoring Divyansh. Let me know and I will publish a new hub on that. Might be possible that there are other people who are looking for the same information.
Bro... "V-22 Osprey in" in TVC class???
Can you please explain your question in detail. I am unable to understand.
where can i get most lateat ysflight simulator
Hey soni , i am also interested in knowing more about TV as i am embarking on a project on that . Is it possible to provide a more in-depth mechanism on how TV actually works ? Thanks !
Hi Siddharth, you can Buy Microsoft Latest Flight Simulator X Deluxe DVD' by Microsoft (Oct 17, 2006) (Pc) for $17.99 http://bit.ly/8X26G3
Definitely David, you can find information on in-depth mechanism on how TV actually works via googling for it. There are a lot of sites which shed light on this.
The writer made a mistake in the second section. Pugachev's Cobra, or the cobra maneuver, as he refers to it in the "What is Thrust Vectoring" section, can be performed by aircraft that DO NOT HAVE thrust vectoring as well. Pugachev's Cobra does not require TVC nozzles. However, the installation of this piece of hardware does make the maneuver much easier.
I think you are right Maverick. I made a mistake and it needs to be corrected honestly. Thanks for the feedback. Feedback help us improve our articles.
SU-30 MKI and F-22 have 1-dimensional thrust vectoring and MIG-35 is the only plane to have 2 dimensional thrust vectoring
Thanks for the additional info "Stones".
As you say "the russians have a separate control for controlling TV of the nozzle". Do you know wich one is the controller and how it works? Where is located in the cockpit?
Thanks, a lot for the article, has been the only one where i found info about the TVC works.
Sorry, Once again, i didnt explained my previous question.
that, "Bro... "V-22 Osprey in" in TVC class???" I mean is V-22 Osprey using Thrust Vectoring Control systems? while V-22 propulsion system is propeller based.
Oh sorry, now i got it. I blindly combined the term 'thrust' only with turbine engines.
nice explanation,a good research.
@Afex, JineshJK, Sidhant, and Glen619, thank you so much for your comments and visit.
Dear,
You do an excellent work. I have too much interest in military machines, especially aircraft. I often spend time on internet and keep sitting in front of computers for hours browsing weapon stuffs. I have written for Daily Loksatta on many topics in Marathi. Including an article on Sukhoi-30MKIs capabilites and had written how it is different and more capable than its Chinese counterpart. Thrust Vectored Engines can allow any flying machine hovor like a helicopter. V-22 Ospray or See Harriers can land on a buliding tarrace as well as in a densed jungle only because of Thrust Vectored Engines. If we can refit our entire existing fleet of Mig-29Bs, we can for some American Aircraft also including F-16IN which is a great aircraft as far as manuerability and accuracy in weapon firing is concerned.
We should think of refiting our 65+ Mig-29Bs with Thrust Vectored Engines of OVTs as said earlier. What are your thaughts on this Soni..?
Hello Vishal Bulbule, this is Soni Chitkule just joking actually Rajinder soni, you have some awesome thoughts bro. Thinking so much about improving our weaponry and aircraft systems is the most important thing, but I doubt if any engineers in the Indian Air Force are reading this. Refitting our 65+ Mig-29Bs with thrust vectored engines is an awesome idea and will add to the Indian Air Force's capability and strength but still we can only think of it. Actually, it is up to them to do this. Anyways, this is a really nice idea of yours and really impressed of your so much interest in fighter aircrafts.
wow impressed so many followers..I wish
Nice good Job
NICE ONE SONI...
I LIKED IT, SUKHOI IS ONE OF THE MOST TECHNICALLY ADVANCED WARCRAFT.
@Vishal Bulbule, @soni2006
Thrust vectoring does not necessarily allow all TVC controlled aircraft to hover like a helicopter. It depends on the control law and the design of the engines and the deflection of the nozzle.
There are only 2 operational jet fighters(not technology demonstrators) that can hover, the harrier jump jets and F-35 lightning since their vectoring is single dimensional. The V-22 osprey can also hover but unlike the above mentioned aircrafts, it has turbo prop engines. The Su-30 MKI, F-22 Raptor have 2D vectoring in the Pitch axis, whereas the SU-35BM, Mig-35, PAK FA have 3D thrust vectoring in the pitch and yaw axis. None of these aircrafts can hover but they can perform maneuvers at very low speeds which would put other conventional aircrafts in a stall.
The MiG 29's are powered by the RD-33 engines and variants of the same, the latest variant being RD-33OVT which powers the Mig 35. Therefore it does not make sense to replace functional engines with new ones and that too on aging airframes(our mig 29s were purchased in the 1980's).
Eurofighter GMBH has offer TVC engines on the EF Typhoons for India if they win the contract for the MMRCA deal.
how you confirmed manufacturing of al 3p by hal . I think it is only assembling . Any confirmation.
very very nice dude
America has been testing TVC on aircraft for a couple of decades now. They have the X31 which you mentioned but they also have / had the following programs.
F-15 ACTIVE
F-15 STOL/MTD
F-16 MATV
F-18 HARV
All 3D thrust vectoring platforms for testing maneuverability, high alpha flight, and other control advantages and disadvantages of TVC.
Yes that is true. However, all of these were test beds and technology demonstrators. The US has only 2 operational TVC controlled fighters. Namely the F22 Raptor and F-35 JSF. Both are 5th generation fighters whereas the test beds were 4th generation fighters (X-31 was an experimental craft by NASA).
Russia used the SU-47 Berkut and Su-37 as test beds for AL-41 FP1 TVC engines as well as radars, avionics and other flight control systems which eventually will make its way into the the PAK FA (also a 5th generation fighter being developed to counter the F-22 and F-35).
The 4++ generation operational fighters controlled by TVC are...
SU 30 variants (MKI, MKM etc)
SU 35 BM
EF typhoon Tranche 3 may be fitted with TVC engines.
Add MiG 35 to the above list.
To Neil
You r right dear. V-22 is only an example of thrust vectoring. Not thrust vectored engine. Fitting Mig-29s with THrust vectored engines is still a good idea i feel. We have just spent a lot on updating 3rd generation Mig-27. Why is it so then..? Only beause we have just purchased these aircraft? only 18 years back. We are also spending a huge amount of money on upgrading Mirage-2000H working with Dassault. According to you all these things must be useless then. Because we purchased Mig-29 and Mirage-2000H at the same time if you know. I know Mig-29 has RD-33. I also read dear.
Ok lets just enjoy Rafale's selection. I am so happy to see this aircraft got selected. It was always my favourite.
126 (200..?) Rafale
270+ Sukhoi 30 MKIs,
200 FGFA
50+ Upgraded Mirage-2kH
60+ Upgraded Mig-29Bs (to Mig-29M3)
Ohh my god...we can rule Asia Pacific Region.
We may also go for some U.S. made fighter aircraft.
May be 40 F-35L-2 in the very recent future.
We have already started operating Russian Mig-29 K which is considered a very good naval jet.
But we have taken 5 extra years in selecting MMRCA. That was an idiot act. Immediate compensation is required for this in the form of some quick purchase of some 20 new combat aircraft to fill the gap created by Mig-25's retirement. We are GARUDLESS since 7 years.
Pravin Yadav 3 years ago
Very nice hub. Really Brilliant information. I am an aviation student and I thank you for writing out this useful article.