Aerodynamics is generally summarized in these 2 terms: “Lift against Weight” and “Thrust against Drag”. This basically means the amount of flight power generated must be equal to, or greater than the amount of weight of the airplane, and the amount of pushing generated, must be equal to or greater than the airs resistance. But the overall question, so far, is how is “Lift” and “Thrust” generated? The answer to how “Thrust” is generated is quite simple. Its sort of how a car would move, except in a much different way. Airplanes have 4 engines, which can each exert easily up to 200 PSI of air (pressure per square inch), composed of liquid fuel cylinders, and internal combustion (like a car). It also tops to 250 km per hour on the runway! But how “Lift” is generated is, the true definition of aerodynamics. The first thing you must consider to understand this is that the wing of the plane is specially designed, to force the air above the wing to rush faster, than the air beneath it. This works according to the “Bernoulli’s principle”. The reason air above the wing must be fast...
Activity #1 FLIGHT A kid named Zits who lives in Seattle, is only fifteen years old. He’s tall, skinny, ugly, and sometimes mean. He also has forty-seven zits and that’s where he gets his name from. Zits is Irish, Indian and is a foster child.
In conclusion it can be seen that lift is derived from the fact that for there to exist a lifting force created in the wings the wings must exert a force on the air around them. The wings are able to do this due to the viscosity of air and the Coanda effect. By manipulating the wing's curves and angle of attack a pilot may preform great stunts and feats not possible if lift were to be explained through other incorect models.
First of all you will have to understand the principles of flight. An airplane flies because air moving over and under its surfaces, particularly its wings, travels at different velocities, producing a difference in air pressure, low above the wing and high below it. The low pressure exerts a pulling influence, and the high pressure a pushing influence. The lifting force, usually called lift, depends on the shape, area, and tilt of the wing, and on the speed of the aircraft. The shape of the wing causes the air streaming above and below the wing to travel at different velocities. The greater distance over which the air must travel above the curved upper surface forces that air to move faster to keep pace with the air moving along the flat lower surface. According to Bernoulli’s principle, it is this difference in air velocity that produces the difference in air pressure.
Aerodynamics is the study of the motion of fluids in the gas state and bodies in motion relative to the fluid/air. In other words the study of aerodynamics is the study of fluid dynamics specifically relating to air or the gas state of matter.
For a plane to create lift, its wings must create low pressure on top and high pressure on the bottom. However, at the tips of the wings, the high pressure pushes and the low pressure pulls air onto the top of the wing, reducing lift and creating a current flowing to the top. This current remains even after the wing has left the area, producing really awesome vortices.
All flight is the result of forces acting upon the wings of an airplane that allow it to counteract gravity. Contrary to popular belief, the Bernoulli principle is not responsible for most of the lift generated by an airplanes wings. Rather, the lift is created by air being deflected off the wings and transferring an upward force to those wings.
The book Flight written by Sherman Alexie is about a 15 year old part Native American
Flight uses four forces: lift, weight, thrust, and drag. In a nutshell; so to speak, an airplane must create enough lift to support its own weight. Secondly, the airplane must produce thrust to propel itself. Finally, the aircraft must overcome the drag or the force of resistance on the airplane that is moving through the air. All four of these forces are vital and necessary for an aircraft to move, takeoff, fly, and land.
Ever since I was little I was amazed at the ability for a machine to fly. I have always wanted to explore ideas of flight and be able to actually fly. I think I may have found my childhood fantasy in the world of aeronautical engineering. The object of my paper is to give me more insight on my future career as an aeronautical engineer. This paper was also to give me ideas of the physics of flight and be to apply those physics of flight to compete in a high school competition.
The character that will be focused on is Whip Whitaker in the movie Flight. Whip Whitaker is a male African-American, pilot that has no religious beliefs or spiritualism in the beginning of the film. Prior to his career with SouthJet Airlines, he was a pilot in the Navy. He is divorced with one son; in the beginning of the film he has a relationship with his co-worker, Katerina, and throughout the movie builds a new romantic relationship with Nicole. While he initially showed lack of faith throughout much of the movie, the change in Whip towards the end of the film demonstrates faith by facing the truth and allowing the higher power to be in control of the next events. Before admitting the truth in the hearing, he mutters “God help me” and proceeds to show integrity and courage despite knowing that the consequence for telling the truth will be jail time for him. He displays courage, valor, and expertise when he takes control of a crashing airplane and saves 96 out of 102 people on board the plane. When he finds out that Katerina as well as 5 other people have been killed, he shows toughness and resilience and is able to overcome the loss he experiences and the guilt he is ridden with. He is an experienced airplane pilot that is courageous, persistent, resilient, and at times, brutally honest. Whip’s coping mechanisms are denial, dissociation, acting out, displacement, and undoing. While he is going through an immensely tumultuous time, he displays resiliency and perseverance to overcome the legal ramifications of the airplane crash that he was piloting. Whip also displays kindness and courage when he rescues Nicole from her landlord that is attempting to beat her, without hesitation. He has diff...
In 1958, the United States government created the Federal Aviation Agency (FAA) because of increasing safety concerns due to aviation accidents. However, they were not the first government organization that regulated air transportation. Even in 1958, the FAA shared certain responsibilities with other organizations. The responsibilities of the FAA at the time were limited when compared to their functions today, but it was an important step to effectively create a safe air transportation environment. To truly understand why the FAA was created, one must first understand the government’s role within the country’s transportation system.
The basic concepts of lift for an airplane is seen. The air that is flowing splits to move around a wing. The air that that moves over the wing speeds up creating lower pressure which means that the higher pressure from the air moving slower under the wing pushes up trying to equalize the pressure. The lift generated can be affected by the angle at which the wing is moving into the flowing air. The more surface area of the wing resisting against the flow of air can either generate lift or make the plane dive. This can be easily simulated in everday life. Next time you are riding in a car with someone stick your hand out the window. Have your fingers pointing in the direction of the motion of the vehicle. Now move your hand up and down slightly. You can feel the lift and drag that your hand creates.
Lift is generated by the air flow around the plane's wing. This effect is explained mostly by Bernoulli's Principle which states that the pressure of the air decreases as the velocity of the air increases. The design of a plane's wing changes the airflow around the wing's surface. The air has farther to travel over the top of the wing than the air traveling below the wing. Therefore, the air traveling above the wing is traveling at a higher velocity than the air traveling below it. As air flows around the wing, a high pressure region with low air velocity is created below the wing, and a low pressure region with high air velocity is created above the wing. The difference between the two pressures generates the lift force. (JEPPESEN 1-11)
What is aerodynamics? The word comes from two Greek words aerios concerning the air, and dynamis, meaning powerful. Aerodynamics is the study of forces and the resulting motion of objects through the air. Humans have been interested in aerodynamics and flying for thousands of years, although flying in a heavier-than-air machine has been possible only in the last hundred years. Aerodynamics affects the motion of a large airliner, a model rocket, a beach ball thrown near the shore, or a kite flying high overhead. The curve ball thrown by big league baseball pitchers gets its curve from aerodynamics.
There are many inventions of the future that people either know or hope will happen and some inventions that people have never thought that would happen in this or the next lifetime. For instance, one piece of future technology that I believe may come to pass is the invention of flying cars. Since the time of being young and watching the Jetsons, many people have been waiting to see the first flying car. While bringing up the idea of a flying car to a lot of people would seem absurd or downright impossible to some, I actually believe that it is very much so possible to create given how far technology has come in the past few decades. I think that it is a very logical conclusion to assume that at some point in the future engineers, car makers, and others will start to pursue other alternatives to avoiding traffic jams and other problems on the road, and instead begin to examine the possibilities of taking to the air as an alternative solution. There is much talk about it over the internet and many people would like to try flying cars. While it would greatly improve traffic for those that prefer staying on the ground, it may prove dangerous in the beginning because of accidents in the air with other cars, planes, trees, and buildings. Some would say though, that the convenience would outweigh the risks because there would not be traffic jams, or detours because of road work. These cars would need something like a GPS system and an anti-wrecking system so people would not run into each other or other objects (How Flying Cars Will Work).