THRUST
Pronunciation (Uk): Dictionary entry overview: What does thrust mean? • THRUST (noun) The noun THRUST has 5 senses: 1. the force used in pushing 2. a strong blow with a knife or other sharp pointed instrument 3. the act of applying force to propel something 4. verbal criticism 5. a sharp hand gesture (resembling a blow) Familiarity information: THRUST used as a noun is common. • THRUST (verb) The verb THRUST has 8 senses: 1. push forcefully 2. press or force 3. make a thrusting forward movement 4. impose or thrust urgently, importunately, or inexorably 5. penetrate or cut through with a sharp instrument 6. force (molten rock) into pre-existing rock 7. push upward 8. place or put with great energy Familiarity information: THRUST used as a verb is common. |
They cannot have the same drag coefficient or the same lift/drag ratio so the rest of I did NOT say they have the same drag coefficient did i ???? in fact i seem to think i said that plane A had 1.5 times the drag of plane B which is NOT saying the drag is the same is it ???:ugh::ugh::ugh: i said they DID have the same lift / drag ratio, purely for the maths, as a theoretical calculation. Why can't they have the same lift/drag ratio. ????? |
In the context of this discussion:
3. (Engineering / Aeronautics)a. a propulsive force produced by the fluid pressure or the change of momentum of the fluid in a jet engine, rocket engine, etc. Source: thrust - definition of thrust by the Free Online Dictionary, Thesaurus and Encyclopedia. |
Sorry Dave but you're wrong here. There are 4 forces acting on a gliding some of the time. Your nasa illustration shows a gliding falling from the sky, BUT if he builds up some speed ( momentum ) and pulls back on the stick good n hard what happens, well he will go back up again against gravity untill he runs out of velocity at Agogee and then gravity will take over again and he will fall to earth again During this upwards flight bit he is using the momentum built up as THRUST, and yes its called thrust becuase the momentum is PUSHING the glider upwards against gravity with the kinetic energy being converted to potential energy that is known as height, as is the tension on a kite string that stops it fluttering away in the wind. so during this upwards flight mode using the momentum as thrust 4 forces are acting on the glider, not 3. |
In the context of this discussion: 3. (Engineering / Aeronautics)a. a propulsive force produced by the fluid pressure or the change of momentum of the fluid in a jet engine, rocket engine, etc. so as a GLIDER does not have any other propulsive unit i was using the word thrust in its correct context. sorry i should of realised this is just a troll fest and not actually based on real science. GB |
Dave i am genuinely interested as to your belief that Newtons second law is relevant.
please explain |
thank you hn39 WE AGREE.
|
Dave i am genuinely interested as to your belief that Newtons second law is relevant. So in your glider example, pulling up into a climb (acceleration) is the result of a force with a vertical component (lift). I can't really put it any more simply. |
Maybe not but you could put it correctly.
immediately you pull up into a climb you start to DECELERATE as you are now being pulled back to earth by GRAVITY. not ACCELERATE. you only have your momentum to FORCE you up which is being taken away by gravity. this is a VERTICAL climb and there is no contribution of lift from the wings by the way. and even if there was, it would still be the force of momentum pushing you along against the drag and gravity 4 forces in play not 3. |
Well ...
The two aircraft shown in post #49 have the same L/D at about 226 kts. At that speed, and only at that speed, both airplanes slow down at the same rate. As the speed reduces below 226 kts the L/D's of the two aircraft will change differently and hence the rate of slowing down will be different, as shown in the graph. P.S. I deleted the above immediately after posting it Because I saw that while writing there had been several new posts and I wanted to read those first. Sorry for any confusion. P.S.2 I suggest you could consider the component of weight that acts in the direction of the flight path as the glider's equivalent of thrust, but momentum is not thrust. |
Read it properly before jumping in. I did NOT say they have the same drag coefficient did i ???? in fact i seem to think i said that plane A had 1.5 times the drag of plane B which is NOT saying the drag is the same is it ???:ugh::ugh::ugh: i said they DID have the same lift / drag ratio, purely for the maths, as a theoretical calculation. Why can't they have the same lift/drag ratio. ????? As to force vs momentum Momentum = mass * velocity Force = mass * acceleration Acceleration = rate of change of velocity Force = rate of change of momentum. |
the force of momentum sorry i should of realised this is just a troll fest and not actually based on real science. |
thank you HN39 we agree yet again, i was merely trying to explain that the gliders equivalent of thrust was its momentum.
But the context police jumped on me looking for a fight. If you understood the basics of how drag varies with lift coefficient and how lift coefficient varies with speed and weight you wouldn't need to ask that question Dave think of a skier going down a ski jump ramp, at the end the ramp curls upwards to the sky, now as the skier gets to the turned up bit what happens to him, oh he goes upwards, is he creating lift, no then what carries upwards as he leaves the ramp, i guess it must be the momentum he built up on the way down. and i don't really care how much you insult me about my knowledge. the force of momentum OK, this is where we came in, I give up. The word "of" from the dictionary. of1 [uhv, ov; unstressed uhv or, especially before consonants, uh] Show IPA preposition 1. (used to indicate distance or direction from, separation, deprivation, etc.): within a mile of the church; south of Omaha; to be robbed of one's money. 2. (used to indicate derivation, origin, or source): a man of good family; the plays of Shakespeare; a piece of cake. 3. (used to indicate cause, motive, occasion, or reason): to die of hunger. 4. (used to indicate material, component parts, substance, or contents): a dress of silk; an apartment of three rooms; a book of poems; a package of cheese. 5. (used to indicate apposition or identity): Is that idiot of a salesman calling again? so you see i was using this word to try to explain that the force is derived from the momentum or that its source was the momentum, not that the 2 words are the same. :mad: |
We have 2 aircraft plane A weighs 300 Tonnes and plane B weighs 200 Tonnes. Both are identical and have the same wing with the same Lift drag ratio of 17 similar to a 747. Both aircraft are cruising straight and level at 400 Km/h. L=q.S.CL D=q.S.CD L/D = CL/CD , that is exclusively dependent on AoA. They can'y fly at the same AoA. As for the slowing down subject: The heavy airplane has more Drag than the light one, when speed is constant. When you cut thrust to idle the difference between thrust required and actual thrust (let's say nil for simplification) is greater: greater retarding force than in the light airplane case, which tends to decrease stopping distance. However, the higher weight airplane has more mass, which tends to increase stopping distance. Which effect prevails? D varies because CD varies, when q and S are constant. CD varies because CL does vary too (they are childrem of the same father, AoA). AoA varies linearly with weight, and so does CL. However, CD is not linear. At lower AoAs, CD varies less than linearly with CL. At higher AoAs the opposite is true. So, at low AoAs, D will vary less than mass for a given weight change. Inertia prevails at low AoAs or high speeds. Mass increase is greater than the drag force increase and as a result acceleration is reduced. At high AoAs or low speeds, air viscosity prevails over inertia. Mass increase is less than the drag force increase and as a result acceleration is increased. At least that is the conclusion I have come to thinking about this. I'm standing by for your comments. |
sorry i keep forgetting i have to explain everything and leave nothing open to deliberate misintrepration But that remark can't go unchallenged. I can't see any evidence of anyone deliberately misinterpreting your posts. We may not agree with them, in fact we don't, but that not the same thing at all. PPRuNe is full of spirited discussions on matters of physics, science, engineering, aeronautics, etc, which we all enjoy and which illustrate why many of us chose aviation as a career. But no poster is infallible. Most of us, if challenged by 3 or 4 people who clearly have some background knowledge of the subject matter, would at least be prepared to consider the possibility that we might be wrong, and to listen to their honest attempts to explain the theory and to provide understandable examples to illustrate it. You might want to pause to reflect on that. |
Gezzs what a blood bath in this thread..
I'm assuming "longer" means dt (more time to) slow down from the same speed Now stop killing the momentum and inertia, it has nothing to do with our problem! First let's have Newton in here: a) Force = Mass * Acc Now take two airplanes with mass M1 and M2 where M2 is heavier: b) M2 = 1.3* M1 The lift produced must be just as big aswell: b) L2 = 1.3 * L1 Now if you want airplane nr 2 to decelerate faster, from (a) and (b), the drag needs to be bigger for the heavier airplaine in respect to it's mass: c1) F2 = M2/a2 remember that F in our case is Drag c2) F1 = M1/a1 and because we need c3) a2> a1 then the drag is automatically: c) D2 > 1.3 *D1 Now combine (c) and (b) a little bit and you end up with a simple condition (d) L2/D2 < L1/D1 Lift/Drag ratio needs to be bigger for the second plane. We know that L2>L1 from (b), and we assumed they both start at the same speed, so it's only Alpha that changes to create more lift: e) Alpha2>Alpha1 (note that we do not know the actual A2/A1 ratio .. it's a matter of wing profile) So we need a better lift/drag ratio (d) for a higher alpha (e) for airplane nr 2. Take a look at a polar Cl/Cd graph. This only happens at speeds below max lift/drag ratio, ie below best glide. Above that speed the ligher airplane will slow down faster. |
but Dave your so called honest attempts to explain that a glider only has 3 forces acting on it was wrong, and it seems once challenged you just resort to insults.
You claimed that a glider only has 3 forces acting on it, yet in the very same article you linked it even states that the glider has 4 forces acting on it. So to say you clearly have a background in the subject when all you rely on is google is a bit rich and highly insulting to those of that rely do have a background in aeronautical engineering. When you fail to win the argument on substance you result to syntax then finally to insults - classic troll behaviour pattern. i have repeatedly stated that my aerodynamics is flawed, i am a thermodynamic engineer who designs jet engines for living, yet when i ask to be enlightened by the "experts" there is no reply. It seems a trait here is that people just want to pull every poster down and show the world they are cleverer than the poster rather than actually discussing a subject, as you have shown without resorting to insults when you can't win. Maybe you would also like to reflect on your posts, re read them and realise that maybe just for this one in a million possibility that you were not correct in stating a glider has only 3 forces acting on it. Oh and i didn't see 3 or 4 other posters supporting your claim as to only 3 forces acting on it, just yours. Kind regards. GB |
Urbandictionary.com:
Troll: One who posts a deliberately provocative message to a newsgroup or message board with the intention of causing maximum disruption and argument |
Oh well, it's a damp Saturday and I have nothing else to do ...
You claimed that a glider only has 3 forces acting on it yet in the very same article you linked it even states that the glider has 4 forces acting on it. "The thrust is determined by the size and type of propulsion system used on the airplane and on the throttle setting selected by the pilot." (those emphases aren't mine, they appear in the original article). The US convention is to use the term "airplane" to mean a powered, fixed-wing aircraft - I used to argue, once upon a time, that gliders were also "airplanes", but I was wrong about that, it's their word and they get to define it. :O The terms "propulsion system" and "throttle" also give a pretty good clue as to what we're talking about here. So please, one more time, tell us all what this mysterious 4th force (in addition to L/D/W) is that acts on a glider in flight ? |
There are only two forces acting on a glider: an aerodynamic force and a gravitational force. The gravitational force is directed towards the center of the earth and is equal to the product of mass m and gravitational acceleration g.
The aerodynamic force is usually represented by its two components: the drag force D acting opposite to the direction of movement, and the lift force L perpendicular to it. For a glider moving at constant altitude the lift force is equal to the gravitational force: L = m * g ... (equation 1) There is no force opposing the drag force so according to Newton's second law there results an acceleration a resulting from the equation: - D = m * a ... (equation 2) (The sign convention is positive for forces and accelerations in the direction of motion, negative in the opposite direction) Combining equations (1) and (2) we get: a / g = - D / L No need to discuss momentum or energy. P.S. If you measure accelerations in kts/second, then g is about 19.05 kts/second |
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