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Transonic (or transsonic) flow is air flowing around an object at a speed that generates regions of both subsonic and supersonic airflow around that object.<ref name=":2" /> The exact range of speeds depends on the object's critical Mach number, but transonic flow is seen at flight speeds close to the speed of sound (343 m/s at sea level), typically between Mach 0.8 and 1.2.<ref name=":2">Template:Cite book</ref>
The issue of transonic speed (or transonic region) first appeared during World War II.<ref name=":0">Template:Cite journal</ref> Pilots found as they approached the sound barrier the airflow caused aircraft to become unsteady.<ref name=":0" /> Experts found that shock waves can cause large-scale separation downstream, increasing drag, adding asymmetry and unsteadiness to the flow around the vehicle.<ref name=":1">Template:Cite book</ref> Research has been done into weakening shock waves in transonic flight through the use of anti-shock bodies and supercritical airfoils.<ref name=":1" />
Most modern jet powered aircraft are engineered to operate at transonic air speeds.<ref>Template:Cite book</ref> Transonic airspeeds see a rapid increase in drag from about Mach 0.8, and it is the fuel costs of the drag that typically limits the airspeed. Attempts to reduce wave drag can be seen on all high-speed aircraft. Most notable is the use of swept wings, but another common form is a wasp-waist fuselage as a side effect of the Whitcomb area rule.
Transonic speeds can also occur at the tips of rotor blades of helicopters and aircraft. This puts severe, unequal stresses on the rotor blade and may lead to accidents if it occurs. It is one of the limiting factors of the size of rotors and the forward speeds of helicopters (as this speed is added to the forward-sweeping [leading] side of the rotor, possibly causing localized transonics).
HistoryEdit
Discovering transonic airflowEdit
Issues with aircraft flight relating to speed first appeared during the supersonic era in 1941.<ref name=":35">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> Ralph Virden, a test pilot, crashed in a fatal plane accident.<ref name=":23">Template:Cite book</ref> He lost control of the plane when a shock wave caused by supersonic airflow developed over the wing, causing it to stall.<ref name=":23" /> Virden flew well below the speed of sound at Mach 0.675, which brought forth the idea of different airflows forming around the plane.<ref name=":35" /> In the 40s, Kelly Johnson became one of the first engineers to investigate the effect of compressibility on aircraft.<ref name=":35" /> However, contemporary wind tunnels did not have the capability to create wind speeds close to Mach 1 to test the effects of transonic speeds.<ref name=":23" /> Not long after, the term "transonic" was defined to mean "across the speed of sound" and was invented by NACA director Hugh Dryden and Theodore von Kármán of the California Institute of Technology.<ref name=":35" />
Changes in aircraftEdit
Initially, NACA designed "dive flaps" to help stabilize the plane when reaching transonic flight.<ref name=":35" /> This small flap on the underside of the plane slowed the plane to prevent shock waves, but this design only delayed finding a solution to aircraft flying at supersonic speed.<ref name=":35" /> Newer wind tunnels were designed, so researchers could test newer wing designs without risking test pilots' lives.<ref name=":4">Template:Cite journal</ref> The slotted-wall transonic tunnel was designed by NASA and allowed researchers to test wings and different airfoils in transonic airflow to find the best wingtip shape for sonic speeds.<ref name=":4" />
After World War II, major changes in aircraft design were seen to improve transonic flight.<ref name=":23" /> The main way to stabilize an aircraft was to reduce the speed of the airflow around the wings by changing the chord of the plane wings, and one solution to prevent transonic waves was swept wings.<ref name=":35" /> Since the airflow would hit the wings at an angle, this would decrease the wing thickness and chord ratio.<ref name=":35" /> Airfoils wing shapes were designed flatter at the top to prevent shock waves and reduce the distance of airflow over the wing.<ref>Template:Cite journal</ref> Later on, Richard Whitcomb designed the first supercritical airfoil using similar principles.<ref name=":4" />
Mathematical analysisEdit
Prior to the advent of powerful computers, even the simplest forms of the compressible flow equations were difficult to solve due to their nonlinearity.<ref name=":23" /> A common assumption used to circumvent this nonlinearity is that disturbances within the flow are relatively small, which allows mathematicians and engineers to linearize the compressible flow equations into a relatively easily solvable set of differential equations for either wholly subsonic or supersonic flows.<ref name=":23" /> This assumption is fundamentally untrue for transonic flows because the disturbance caused by an object is much larger than in subsonic or supersonic flows; a flow speed close to or at Mach 1 does not allow the streamtubes (3D flow paths) to contract enough around the object to minimize the disturbance, and thus the disturbance propagates.<ref name=":13">Template:Cite book</ref> Aerodynamicists struggled during the earlier studies of transonic flow because the then-current theory implied that these disturbances– and thus drag– approached infinity as local Mach number approached 1, an obviously unrealistic result which could not be remedied using known methods.<ref name=":23" />
One of the first methods used to circumvent the nonlinearity of transonic flow models was the hodograph transformation.<ref name=":0" /> This concept was originally explored in 1923 by an Italian mathematician named Francesco Tricomi, who used the transformation to simplify the compressible flow equations and prove that they were solvable.<ref name=":0" /> The hodograph transformation itself was also explored by both Ludwig Prandtl and O.G. Tietjen's textbooks in 1929 and by Adolf Busemann in 1937, though neither applied this method specifically to transonic flow.<ref name=":0" />
Gottfried Guderley, a German mathematician and engineer at Braunschweig, discovered Tricomi's work in the process of applying the hodograph method to transonic flow near the end of World War II.<ref name=":0" /> He focused on the nonlinear thin-airfoil compressible flow equations, the same as what Tricomi derived, though his goal of using these equations to solve flow over an airfoil presented unique challenges.<ref name=":0" /><ref name=":23" /> Guderley and Hideo Yoshihara, along with some input from Busemann, later used a singular solution of Tricomi's equations to analytically solve the behavior of transonic flow over a double wedge airfoil, the first to do so with only the assumptions of thin-airfoil theory.<ref name=":0" /><ref name=":23" />
Although successful, Guderley's work was still focused on the theoretical, and only resulted in a single solution for a double wedge airfoil at Mach 1.<ref name=":0" /> Walter Vincenti, an American engineer at Ames Laboratory, aimed to supplement Guderley's Mach 1 work with numerical solutions that would cover the range of transonic speeds between Mach 1 and wholly supersonic flow.<ref name=":0" /> Vincenti and his assistants drew upon the work of Howard Emmons as well as Tricomi's original equations to complete a set of four numerical solutions for the drag over a double wedge airfoil in transonic flow above Mach 1.<ref name=":0" /> The gap between subsonic and Mach 1 flow was later covered by both Julian Cole and Leon Trilling, completing the transonic behavior of the airfoil by the early 1950s.<ref name=":0" />
Condensation cloudsEdit
At transonic speeds supersonic expansion fans form intense low-pressure, low-temperature areas at various points around an aircraft. If the temperature drops below the dew point a visible cloud will form. These clouds remain with the aircraft as it travels. It is not necessary for the aircraft as a whole to reach supersonic speeds for these clouds to form. Typically, the tail of the aircraft will reach supersonic flight while the nose of the aircraft is still in subsonic flight. A bubble of supersonic expansion fans terminating by a wake shockwave surround the tail. As the aircraft continues to accelerate, the supersonic expansion fans will intensify and the wake shockwave will grow in size until infinity is reached, at which point the bow shockwave forms. This is Mach 1 and the Prandtl–Glauert singularity.
Transonic flows in astronomy and astrophysicsEdit
In astrophysics, wherever there is evidence of shocks (standing, propagating or oscillating), the flow close by must be transonic, as only supersonic flows form shocks. All black hole accretions are transonic.<ref>Template:Cite book</ref> Many such flows also have shocks very close to the black holes.
The outflows or jets from young stellar objects or disks around black holes can also be transonic since they start subsonically and at a far distance they are invariably supersonic. Supernovae explosions are accompanied by supersonic flows and shock waves. Bow shocks formed in solar winds are a direct result of transonic winds from a star. It had been long thought that a bow shock was present around the heliosphere of the Solar System, but this was found not to be the case according to IBEX data published in 2012.<ref>Template:Citation.</ref>
See alsoEdit
- Anti-shock body
- Subsonic flows
- Supersonic flows
- Hypersonic flows
- Supersonic expansion fans