How fast do supersonic fighters fly? Supersonic aircraft

Africa

On February 6, 1950, during another test, the Soviet jet fighter MiG-17 exceeded the speed of sound in horizontal flight, accelerating to almost 1070 km/h. This turned it into the first mass-produced supersonic aircraft. The developers Mikoyan and Gurevich were clearly proud of their brainchild.

For combat flights, the MiG-17 was considered transonic, since its cruising speed did not exceed 861 km/h. But this did not stop the fighter from becoming one of the most common in the world. At various times it was in service with Germany, China, Korea, Poland, Pakistan and dozens of other countries. This monster even took part in the fighting in the Vietnam War.

The MiG-17 is far from the only representative of the supersonic aircraft genre. We will tell you about a dozen more airliners that also outpaced the sound wave and became famous throughout the world.

Bell X-1

The US Air Force specially equipped the Bell X-1 with a rocket engine because they wanted to use it to study the problems of supersonic flight. On October 14, 1947, the device accelerated to 1541 km/h (Mach number 1.26), overcame a given barrier and turned into a star in the sky. Today, the record-breaking model rests in the Smithsonian Museum in the States.

Source: NASA

North American X-15

The North American X-15 is also equipped with rocket engines. But, unlike its American counterpart Bell X-1, this aircraft reached a speed of 6167 km/h (Mach number 5.58), becoming the first and for 40 years the only manned hypersonic aircraft in human history (since 1959). who performed suborbital manned space flights. With its help, they even studied the reaction of the atmosphere to the entry of winged bodies into it. A total of three units of X-15 type rocket planes were produced.

Source: NASA

Lockheed SR-71 Blackbird

It’s a sin not to use supersonic aircraft for military purposes. Therefore, the US Air Force designed the Lockheed SR-71 Blackbird, a strategic reconnaissance aircraft with a maximum speed of 3,700 km/h (Mach number 3.5). The main advantages are fast acceleration and high maneuverability, which allowed it to evade missiles. The SR-71 was also the first aircraft to be equipped with radar signature reduction technologies.

Only 32 units were built, 12 of which crashed. In 1998 it was withdrawn from service.

Source: af.mil

MiG-25

We cannot help but recall the domestic MiG-25 - a 3rd generation supersonic high-altitude fighter-interceptor with a maximum speed of 3000 km/h (Mach number 2.83). The plane was so cool that even the Japanese coveted it. Therefore, on September 6, 1976, Soviet pilot Viktor Belenko had to hijack a MiG-25. After this, for many years in many parts of the Union, aircraft began to be incompletely refueled. The goal is to prevent them from flying to the nearest foreign airport.

Source: Alexey Beltyukov

MiG-31

Soviet scientists did not stop working for the aerial benefit of the fatherland. Therefore, in 1968, the design of the MiG-31 began. And on September 16, 1975, he was in the sky for the first time. This two-seat supersonic all-weather long-range fighter-interceptor accelerated to a speed of 2500 km/h (Mach number 2.35) and became the first Soviet fourth-generation combat aircraft.

The MiG-31 is designed to intercept and destroy air targets at extremely small, small, medium and high altitudes, day and night, in simple and difficult weather conditions, with active and passive radar interference, as well as false thermal targets. Four MiG-31s can control air space length up to 900 kilometers. This is not an airplane, but the pride of the Union, which is still in service with Russia and Kazakhstan.

Source: Vitaly Kuzmin

Lockheed/Boeing F-22 Raptor

The most expensive supersonic aircraft were built by the Americans. They modeled a fifth-generation multirole fighter, which became the most expensive among their colleagues. The Lockheed/Boeing F-22 Raptor is currently the only fifth-generation fighter in service and the first production fighter with a supersonic cruising speed of 1,890 km/h (Mach 1.78). Maximum speed 2570 km/h (Mach 2.42). No one has ever surpassed him in the air.

Source: af.mil

Su-100/T-4

The Su-100/T-4 (“weaving”) was developed as an aircraft carrier fighter. But the engineers of the Sukhoi Design Bureau managed not only to achieve their goal, but to simulate a cool attack and reconnaissance bomber-missile carrier, which they then wanted to use even as passenger plane and an accelerator for the Spiral aerospace system. The maximum speed of the T-4 is 3200 km/h (Mach 3).

Tu-144 is a Soviet supersonic aircraft developed by the Tupolev Design Bureau in the 1960s. Along with Concorde, it is one of only two supersonic airliners ever used by airlines for commercial travel.

In the 60s, projects to create a passenger supersonic aircraft with a maximum speed of 2500-3000 km/h and a flight range of at least 6-8 thousand km were actively discussed in aviation circles in the USA, Great Britain, France and the USSR. In November 1962, France and Great Britain signed an agreement on the joint development and construction of Concorde (Concord).

Creators of a supersonic aircraft

In the Soviet Union, the design bureau of academician Andrei Tupolev was involved in the creation of a supersonic aircraft. At a preliminary meeting of the Design Bureau in January 1963, Tupolev stated:

“Reflecting on the future of air transportation of people from one continent to another, you come to a clear conclusion: supersonic airliners are undoubtedly needed, and I have no doubt that they will come into practice...”

The academician's son, Alexey Tupolev, was appointed as the lead designer of the project. More than a thousand specialists from other organizations worked closely with his design bureau. The creation was preceded by extensive theoretical and experimental work, which included numerous tests in wind tunnels and natural conditions during analogue flights.

Concorde and Tu-144

The developers had to rack their brains to find the optimal design for the machine. The speed of the designed airliner is fundamentally important - 2500 or 3000 km/h. The Americans, having learned that the Concorde is designed for 2500 km/h, announced that just six months later they would release their passenger Boeing 2707, made of steel and titanium. Only these materials could withstand the heating of the structure when in contact with air flow at speeds of 3000 km/h and above without destructive consequences. However, solid steel and titanium structures must still undergo serious technological and operational testing. This will take a lot of time, and Tupolev decides to build a supersonic aircraft from duralumin, designed for a speed of 2500 km/h. The American Boeing project was subsequently completely closed.

In June 1965, the model was shown at the annual Paris Air Show. Concorde and Tu-144 turned out to be strikingly similar to each other. Soviet designers said - nothing surprising: the general shape is determined by the laws of aerodynamics and the requirements for a certain type of machine.

Supersonic aircraft wing shape

But what should the wing shape be? We settled on a thin delta wing with the front edge shaped like the letter “8”. The tailless design - inevitable with such a design of the load-bearing plane - made the supersonic airliner stable and well controllable in all flight modes. Four engines were located under the fuselage, closer to the axis. The fuel is placed in coffered wing tanks. The trim tanks, located in the rear fuselage and wing flaps, are designed to change the position of the center of gravity during the transition from subsonic to supersonic flight speeds. The nose was made sharp and smooth. But how can pilots have forward visibility in this case? They found a solution - the “bowing nose.” The fuselage had a circular cross-section and had a cockpit nose cone that tilted downward at an angle of 12 degrees during takeoff and 17 degrees during landing.

Supersonic plane takes to the sky

The first supersonic aircraft took to the skies on the last day of 1968. The car was flown by test pilot E. Elyan. As a passenger aircraft, it was the first in the world to overcome the speed of sound in early June 1969, while at an altitude of 11 kilometers. The supersonic aircraft reached the second speed of sound (2M) in mid-1970, at an altitude of 16.3 kilometers. The supersonic aircraft incorporates many design and technical innovations. Here I would like to note such a solution as the front horizontal tail. When using PGO, flight maneuverability was improved and speed was reduced during landing. The domestic supersonic aircraft could be operated from two dozen airports, while the French-English Concorde, having a high landing speed, could land only at a certified airport. The designers of the Tupolev Design Bureau did a tremendous job. Take, for example, full-scale tests of a wing. They took place on a flying laboratory - the MiG-21I, modified specifically for testing the design and equipment of the wing of the future supersonic aircraft.

Development and modification

Work on the development of the basic “044” design went in two directions: the creation of a new economical afterburning turbojet engine of the RD-36-51 type and a significant improvement in the aerodynamics and design of the supersonic aircraft. The result of this was to meet the requirements for supersonic flight range. The decision of the commission of the USSR Council of Ministers on the version of the supersonic aircraft with the RD-36-51 was made in 1969. At the same time, at the proposal of the MAP - MGA, a decision is made, before the creation of the RD-36-51 and their installation on a supersonic aircraft, on the construction of six supersonic aircraft with the NK-144A with reduced specific fuel consumption. The design of serial supersonic aircraft with the NK-144A was supposed to be significantly modernized, significant changes in aerodynamics would be made, obtaining a Kmax of more than 8 in supersonic cruising mode. This modernization was supposed to ensure the fulfillment of the requirements of the first stage in terms of range (4000-4500 km), and in the future it was planned to transition to series on RD-36-51.

Construction of a modernized supersonic aircraft

Construction of the pre-production modernized Tu-144 (“004”) began at MMZ “Experience” in 1968. According to calculated data with NK-144 engines (Cp = 2.01), the estimated supersonic range should have been 3275 km, and with NK-144A (Cp = 1.91) it should have exceeded 3500 km. In order to improve the aerodynamic characteristics in cruising mode M = 2.2, the wing planform was changed (the sweep of the floating part along the leading edge was reduced to 76°, and the base part was increased to 57°), the shape of the wing became closer to “Gothic”. Compared to "044", the wing area has increased, and a more intense conical twist of the wing ends has been introduced. However, the most important innovation in wing aerodynamics was the change in the middle part of the wing, which ensured self-balancing in cruising mode with minimal losses quality, taking into account optimization for flight deformations of the wing in this mode. The length of the fuselage was increased to accommodate 150 passengers, and the shape of the nose was improved, which also had a positive effect on aerodynamics.

Unlike “044”, each pair of engines in paired engine nacelles with air intakes was moved apart, freeing the lower part of the fuselage from them, unloading it from increased temperature and vibration loads, while changing the lower surface of the wing in the place of the calculated area of flow compression, increasing the gap between the lower surface wing and the upper surface of the air intake - all this made it possible to more intensively use the effect of compressing the flow at the entrance to the air intakes on the Kmax than was possible to achieve on the “044”. The new layout of the engine nacelles required changes to the chassis: the main landing gear was placed under the engine nacelles, with them retracted inside between the air ducts of the engines, they switched to an eight-wheeled trolley, and the scheme for retracting the nose landing gear also changed. An important difference between the “004” and the “044” was the introduction of a front multi-section destabilizer wing retractable in flight, which extended from the fuselage during takeoff and landing modes, and made it possible to provide the required balancing when the elevons-flaps were deflected. Design improvements, an increase in payload and fuel reserves led to an increase in take-off weight, which exceeded 190 tons (for “044” - 150 tons).

Pre-production Tu-144

Construction of pre-production supersonic aircraft No. 01-1 (tail No. 77101) was completed at the beginning of 1971, and made its first flight on June 1, 1971. According to the factory test program, the vehicle completed 231 flights, lasting 338 hours, of which 55 hours flew at supersonic speed. This machine was used to work out complex issues regarding the interaction of the power plant in various flight modes. On September 20, 1972, the car flew along the Moscow-Tashkent highway, while the route was covered in 1 hour 50 minutes, the cruising speed during the flight reached 2500 km/h. The pre-production vehicle became the basis for the deployment of serial production at the Voronezh Aviation Plant (VAZ), which, by decision of the government, was entrusted with the development of a supersonic aircraft in a series.

First flight of the production Tu-144

The first flight of serial supersonic aircraft No. 01-2 (tail No. 77102) with NK-144A engines took place on March 20, 1972. In the series, based on the results of tests of the pre-production vehicle, the aerodynamics of the wing were adjusted and its area was once again slightly increased. The take-off weight in the series reached 195 tons. By the time of operational testing of production vehicles, the specific fuel consumption of the NK-144A was intended to be increased to 1.65-1.67 kg/kgf/hour by optimizing the engine nozzle, and subsequently to 1.57 kg/kgf/hour, while the flight range should was increased to 3855-4250 km and 4550 km, respectively. In reality, they were able to achieve by 1977, during testing and development of the Tu-144 and NK-144A series, Average = 1.81 kg/kgf hour in cruising supersonic thrust mode 5000 kgf, Average = 1.65 kg/kgf hour in takeoff afterburner thrust mode 20,000 kgf, Av = 0.92 kg/kgf per hour in the cruising subsonic mode of thrust 3000 kgf and in the maximum afterburning mode in the transonic mode we received 11,800 kgf. A fragment of a supersonic aircraft.

Flights and tests of a supersonic aircraft

First stage of testing

In a short period of time, in strict accordance with the program, 395 flights were completed with a total flight time of 739 hours, including more than 430 hours in supersonic modes.

Second stage of testing

At the second stage of operational testing in accordance with the joint order of ministers aviation industry And civil aviation dated September 13, 1977 No. 149-223, there was a more active connection of civil aviation facilities and services. A new testing commission was formed, headed by Deputy Minister of Civil Aviation B.D. Rude. By decision of the commission, then confirmed by a joint order dated September 30 - October 5, 1977, crews were appointed to conduct operational tests:

First crew: pilots B.F. Kuznetsov (Moscow State Transport Administration), S.T. Agapov (ZhLIiDB), navigator S.P. Khramov (MTU GA), flight engineers Yu.N. Avaev (MTU GA), Yu.T. Seliverstov (ZhLIiDB), leading engineer S.P. Avakimov (ZhLIiDB).
Second crew: pilots V.P. Voronin (MSU GA), I.K. Vedernikov (ZhLIiDB), navigator A.A. Senyuk (MTU GA), flight engineers E.A. Trebuntsov (MTU GA) and V.V. Solomatin (ZhLIiDB), leading engineer V.V. Isaev (GosNIIGA).
Third crew: pilots M.S. Kuznetsov (GosNIIGA), G.V. Voronchenko (ZhLIiDB), navigator V.V. Vyazigin (GosNIIGA), flight engineers M.P. Isaev (MTU GA), V.V. Solomatin (ZhLIiDB), leading engineer V.N. Poklad (ZhLIiDB).
Fourth crew: pilots N.I. Yurskov (GosNIIGA), V.A. Sevankaev (ZhLIiDB), navigator Yu.A. Vasiliev (GosNIIGA), flight engineer V.L. Venediktov (GosNIIGA), leading engineer I.S. Mayboroda (GosNIIGA).

Before testing began, a lot of work was done to review all the materials received in order to use them “for credit” for meeting specific requirements. However, despite this, some civil aviation specialists insisted on implementing the “Operational Test Program for Supersonic Aircraft,” developed at GosNIIGA back in 1975 under the leadership of leading engineer A.M. Teteryukov. This program essentially required the repetition of previously completed flights in the amount of 750 flights (1200 flight hours) on MGA routes.

The total volume of operational flights and tests for both stages will be 445 flights with 835 flight hours, of which 475 hours are in supersonic modes. 128 paired flights were performed on the Moscow-Alma-Ata route.

The final stage

The final stage of testing was not stressful from a technical point of view. Rhythmic work according to schedule was ensured without serious failures or major defects. The engineering and technical crews “had fun” by assessing household equipment in preparation for passenger transportation. Flight attendants and relevant specialists from GosNIIGA, who were involved in the tests, began to conduct ground training to develop the technology for servicing passengers in flight. The so-called “pranks” and two technical flights with passengers. The “raffle” was held on October 16, 1977 with a complete simulation of the cycle of ticket check-in, baggage check-in, passenger boarding, flight of actual duration, passenger disembarkation, baggage check-in at the destination airport. There was no end to the “passengers” (the best workers of OKB, ZhLIiDB, GosNIIGA and other organizations). The diet during the “flight” was top level, since it was confirmed according to the first class menu, everyone thoroughly enjoyed it. The “draw” made it possible to clarify many important elements and details of passenger service. On October 20 and 21, 1977, two technical flights were carried out along the Moscow-Alma-Ata highway with passengers. The first passengers were employees of many organizations that were directly involved in the creation and testing of the supersonic aircraft. Today it is even difficult to imagine the atmosphere on board: there was a feeling of joy and pride, great hope for development against the backdrop of first-class service, to which technical people are absolutely not accustomed. On the first flights, all the heads of the parent institutes and organizations were on board.

The road is open for passenger traffic

The technical flights took place without serious problems and showed the full readiness of the supersonic aircraft and all ground services To regular transportation. On October 25, 1977, the Minister of Civil Aviation of the USSR B.P. Bugaev and the Minister of Aviation Industry of the USSR V.A. Kazakov approved the main document: “Act on the results of operational tests of a supersonic aircraft with NK-144 engines” with a positive conclusion and conclusions.

Based on the presented tables of compliance of the Tu-144 with the requirements of the Temporary Airworthiness Standards for Civilian Tu-144 of the USSR, the full volume of submitted evidentiary documentation, including acts on state and operational tests, on October 29, 1977, Chairman of the State Aviation Register of the USSR I.K. Mulkijanov approved the conclusion and signed the first airworthiness certificate in the USSR, type No. 03-144, for a supersonic aircraft with NK-144A engines.

The road was open for passenger traffic.

The supersonic aircraft could land and take off at 18 airports in the USSR, while Concorde, whose takeoff and landing speed was 15% higher, required a separate landing certificate for each airport. According to some experts, if the Concorde engines had been placed in the same way as the Tu-144, the accident on July 25, 2000 would not have occurred.

According to experts, the design of the Tu-144 airframe was ideal, but the shortcomings concerned the engines and various systems.

The second production copy of a supersonic aircraft

In June 1973, the 30th International Paris Air Show took place in France. There was enormous interest generated by the Soviet airliner Tu-144 - the first in the world supersonic aircraft. On June 2, thousands of visitors to the air show in the Paris suburb of Le Bourget watched the exit to runway the second production copy of a supersonic aircraft. The roar of four engines, a powerful take-off - and now the car is in the air. The sharp nose of the airliner straightened and aimed at the sky. The supersonic Tu, led by Captain Kozlov, made its first demonstration flight over Paris: having gained the required altitude, the car went beyond the horizon, then returned and circled over the airfield. The flight proceeded normally, no technical problems were noted.

The next day, the Soviet crew decided to show everything that the new one was capable of.

Disaster during demonstration

The sunny morning of June 3 did not seem to foretell trouble. At first everything went according to plan - the audience raised their heads and applauded in unison. Supersonic aircraft showing " top class", went down. At that moment, a French Mirage fighter appeared in the air (as it later turned out, it was filming an air show). A collision seemed inevitable. In order not to crash into the airfield and spectators, the crew commander decided to rise higher and pulled the steering wheel towards himself. However, the height had already been lost, creating large loads on the structure; As a result, the right wing cracked and fell off. A fire started there, and a few seconds later the flaming supersonic plane rushed to the ground. A terrible landing occurred on one of the streets of the Parisian suburb of Goussainville. The giant machine, destroying everything in its path, crashed to the ground and exploded. The entire crew - six people - and eight Frenchmen on the ground were killed. Goosenville also suffered - several buildings were destroyed. What led to the tragedy? According to most experts, the cause of the disaster was the attempt of the crew of a supersonic aircraft to avoid a collision with the Mirage. During landing, the Tu was caught in a wake from the French Mirage fighter.

Video: Tu-144 crash in 1973: how it happened

This version is given in Gene Alexander’s book “Russian Airplanes Since 1944” and in an article in Aviation Week and Space Technology magazine for June 11, 1973, written on fresh tracks. The authors believe that pilot Mikhail Kozlov landed on the wrong runway - either due to a mistake by the flight director, or due to the carelessness of the pilots. The controller noticed the error in time and warned the Soviet pilots. But instead of going around, Kozlov made a sharp turn - and found himself right in front of the French Air Force fighter. At that time, the co-pilot was filming a story about the Tu crew for French television with a movie camera and therefore was not wearing a seatbelt. During the maneuver, he fell onto the center console, and while he was returning to his place, he had already lost altitude. Kozlov sharply pulled the steering wheel towards himself - overload: the right wing could not stand it. Here's another explanation terrible tragedy. Kozlov received orders to get the most out of the car. Even during takeoff, at low speed, he took an almost vertical angle. For a liner with such a configuration, this is fraught with enormous overloads. As a result, one of the external nodes could not stand it and fell off.

According to the employees of the A.N. Tupolev Design Bureau, the cause of the disaster was the connection of an undebugged analog block of the control system, which led to a destructive overload.

The spy version belongs to writer James Alberg. Briefly it is like this. The Soviets tried to “furnish” the Concorde. Group N.D. Kuznetsova created good engines, but they could not operate at low temperatures, unlike the Concorde ones. Then Soviet intelligence officers got involved. Penkovsky, through his agent Greville Wine, obtained part of the Concorde drawings and sent them to Moscow through an East German trade representative. British counterintelligence thus identified the leak, but instead of arresting the spy, it decided to let disinformation into Moscow through his own channels. As a result, the Tu-144 was born, very similar to the Concorde. It is difficult to establish the truth, since the “black boxes” did not clarify anything. One was found in Bourges, at the crash site, but, judging by reports, damaged. The second one was never discovered. It is believed that the “black box” of a supersonic aircraft has become a point of contention between the KGB and the GRU.

According to the pilots, emergency situations occurred on almost every flight. On May 23, 1978, the second supersonic plane crashed. An improved experimental version of the airliner, Tu-144D (No. 77111), after a fuel fire in the engine nacelle area of the 3rd power plant due to the destruction of the fuel line, smoke in the cabin and the crew turning off two engines, forced landing in a field near the village of Ilyinsky Pogost, not far from the city of Yegoryevsk.

After landing, crew commander V.D. Popov, co-pilot E.V. Elyan and navigator V.V. Vyazigin left the plane through the cockpit window. Engineers V.M. Kulesh, V.A. Isaev, V.N. Stolpovsky, who were in the cabin, left the aircraft through the front entrance door. Flight engineers O. A. Nikolaev and V. L. Venediktov were trapped in their workplace by structures that were deformed during landing and died. (The deflected nose cone touched the ground first, worked like a bulldozer blade, picking up dirt, and rotated under its belly, entering the fuselage.) On June 1, 1978, Aeroflot stopped supersonic passenger flights forever.

Improving supersonic aircraft

Work on improving the supersonic aircraft continued for several more years. Five production aircraft were produced; another five were under construction. A new modification has been developed - Tu-144D (long-range). However, the choice of a new engine (more economical), RD-36-51, required significant redevelopment of the aircraft, especially power plant. Serious design gaps in this area led to a delay in the release of the new airliner. Only in November 1974, the serial Tu-144D (tail number 77105) took off, and nine (!) years after its first flight, on November 1, 1977, the supersonic aircraft received a certificate of airworthiness. Passenger flights opened on the same day. During their short operation, the liners carried 3,194 passengers. On May 31, 1978, flights were stopped: a fire broke out on one of the production Tu-144Ds, and the airliner suffered a disaster, crashing during an emergency landing.

The disasters in Paris and Yegoryevsk led to a decrease in government interest in the project. From 1977 to 1978, 600 problems were identified. As a result, already in the 80s, it was decided to remove the supersonic aircraft, explaining this with “a bad effect on people’s health when crossing the sound barrier.” Nevertheless, four out of five Tu-144Ds in production were still completed. Subsequently, they were based in Zhukovsky and took to the air as flying laboratories. A total of 16 supersonic aircraft were built (including long-range modifications), which made a total of 2,556 sorties. By the mid-90s, ten of them had survived: four in museums (Monino, Kazan, Kuibyshev, Ulyanovsk); one remained at the plant in Voronezh, where it was built; another one was in Zhukovsky along with four Tu-144Ds.

Subsequently, the Tu-144D was used only for freight transport between Moscow and Khabarovsk. In total, the supersonic aircraft made 102 flights under the Aeroflot flag, of which 55 were passenger flights (3,194 passengers were carried).

Later, supersonic aircraft only made test flights and a few flights to set world records.

The Tu-144LL was equipped with NK-32 engines due to the lack of serviceable NK-144 or RD-36-51, similar to those used on the Tu-160, various sensors and test monitoring and recording equipment.

A total of 16 Tu-144 airliners were built, which made a total of 2,556 sorties and flew 4,110 hours (among them, aircraft 77144 flew the most, 432 hours). The construction of four more airliners was never completed.

What happened to the planes

A total of 16 were built - sides 68001, 77101, 77102, 77105, 77106, 77107, 77108, 77109, 77110, 77111, 77112, 77113, 77114, 77115, 77116 and 77144.

Those remaining in flying condition do not currently exist. The sides of the Tu-144LL No. 77114 and TU-144D No. 77115 are almost completely complete with parts and can be restored to flight condition.

In repairable condition, TU-144LL No. 77114, which was used for NASA tests, is stored at the airfield in Zhukovsky.

TU-144D No. 77115 is also stored at the airfield in Zhukovsky. In 2007, both airliners were repainted and exhibited for public viewing at the MAKS-2007 air show.

No. 77114 and No. 77115 will most likely be installed as monuments or displayed at the airfield in Zhukovsky. In 2004-2005, some transactions were made with them to sell them for scrap metal, but protests from the aviation community led to their preservation. The danger of selling them for scrap metal has not been completely eliminated. The questions of whose ownership they will become have not been finally resolved.

The photograph contains the signature of the first cosmonaut who landed on the moon, Neil Armstrong, pilot cosmonaut Georgiy Timofeevich Beregovoy and all the dead crew members. Supersonic aircraft No. 77102 crashed during a demonstration flight at the Le Bourget air show. All 6 crew members (Honored test pilot Hero of the Soviet Union M.V. Kozlov, test pilot V.M. Molchanov, navigator G.N. Bazhenov, deputy chief designer, engineer Major General V.N. Benderov, leading engineer B.A. Pervukhin and flight engineer A.I. Dralin) died.

From left to right. Six crew members on board supersonic aircraft No. 77102: Honored Test Pilot Hero of the Soviet Union M.V. Kozlov, Test Pilot V.M. Molchanov, Navigator G.N. Bazhenov, Deputy Chief Designer, Engineer Major General V.N. Benderov, leading engineer B.A. Pervukhin and flight engineer A.I. Dralin (unfortunately, she did not specify who is in order). Next is the pilot-cosmonaut twice Hero of the Soviet Union, Major General Georgy Timofeevich Beregovoy, behind him on the left is Vladimir Aleksandrovich Lavrov, then the first American cosmonaut to land on the moon Neil Armstrong, then (standing behind Neil) - Stepan Gavrilovich Korneev (head of the Internal Affairs Directorate from the Department of External Relations Presidium of the Academy of Sciences), in the center Andrey Nikolaevich Tupolev - Soviet aircraft designer, academician of the USSR Academy of Sciences, Colonel General, three times Hero of Socialist Labor, Hero of Labor of the RSFSR, then Alexander Alexandrovich Arkhangelsky, chief designer of the plant, Soviet aircraft designer, Doctor of Technical Sciences, Honored Scientist and technicians of the RSFSR, Hero of Socialist Labor. Far right is Tupolev Alexey Andreevich (son of A.N. Tupolev) - Russian aircraft designer, academician of the Russian Academy of Sciences, academician of the USSR Academy of Sciences since 1984, Hero of Socialist Labor. The photo was taken in 1970. Captions on the photo of G.T. Beregovoy and Neil Armstrong.

Concord

Concorde accident.

Currently, the liner is not in operation due to the disaster on July 25, 2000. April 10, 2003 British Airways And Air France announced the decision to cease commercial operation of its Concorde fleet. The last flights took place on October 24. Concorde's final flight took place on November 26, 2003, with G-BOAF (the last aircraft built) departing Heathrow, flying over the Bay of Biscay, passing over Bristol, and landing at Filton Airport.

Why are supersonic aircraft no longer in use?

Tupolev's supersonic aircraft is often called the "lost generation." Intercontinental flights are considered uneconomical: per hour of flight, a supersonic plane burns eight times more fuel than a regular passenger plane. For the same reason, long-distance flights to Khabarovsk and Vladivostok were not justified. It is not advisable to use the supersonic Tu as a transport airliner due to its small carrying capacity. Is it true, Passenger Transportation it nevertheless became a prestigious and profitable business for Aeroflot, although tickets were considered very expensive at that time. Even after the official closure of the project, in August 1984, the head of the Zhukovsky flight test base Klimov, the head of the design department Pukhov and deputy chief designer Popov, with the support of supersonic flight enthusiasts, restored and put into operation two airliners, and in 1985 they obtained permission to fly for setting world records. The crews of Aganov and Veremey set more than 18 world records in the class of supersonic aircraft - in speed, climb rate and flight range with cargo.

On March 16, 1996, a series of research flights of the Tu-144LL began in Zhukovsky, which marked the beginning of the development of the second generation of supersonic passenger airliners.

95-99 years. The supersonic aircraft with tail number 77114 was used by the American NASA as a flying laboratory. Received the name Tu-144LL. The main purpose is research and testing of American developments to create our own modern supersonic aircraft for passenger transportation.

Throughout history, man has been drawn to overcome all possible barriers. One of them has long been the speed of sound. On this moment There are many supersonic aircraft, some of which are actively used by various countries, while others, for one reason or another, no longer take to the skies.

In the course of development, which was carried out over many decades, not only supersonic fighters for military purposes were designed, but also civilian airliners, some of which carried passengers.

The development of aircraft capable of exceeding it began in the middle of the last century. This happened during the Second World War, when German scientists were hard at work trying to develop a supersonic aircraft that could turn the tide of the war.

However, the war ended, and many German scientists who worked on these developments were captured by the Americans. Largely thanks to them, the USA developed an aircraft with rocket engines - the Bell X-1, on which in 1947 Chuck Yeager was the first in the world to exceed the speed of sound.

A year later I came to a similar result Soviet Union, having developed the LA-176, which first equaled the speed of sound at an altitude of 9000 meters, and a month later, having received improved engines, exceeded it at an altitude of 7000 meters.

Unfortunately, the project was closed due to the tragic death of O.V. Sokolovsky, one of the pilots of this plane. Further progress in the design of supersonic aircraft slowed down due to some physical obstacles: air liquefaction at too high a speed, changes in aerodynamics and streamlining. A serious obstacle was the overheating of aircraft breaking the sound barrier. This phenomenon is called "flutter".

Over the next few years, designers worked on streamlining, aerodynamics, body materials and other improvements.

Military aviation in the 1950s

At the beginning of this decade, the F-100 Super Saber and MiG-19 were developed by the USA and USSR, competing in all spheres. At first, the American F-100 overtook the Soviet Mig, reaching a speed of 1,215 kilometers per hour in 1953, but a year later the Soviet MiG was able to get ahead of it, accelerating to 1,450 kilometers per hour.

Despite the absence of open military clashes between the USA and the USSR, in the local conflicts of the Vietnam and Korean wars it was established that the Soviet MiG was in many ways superior to its American competitor.

The MiG-19 was lighter, took to the air faster, surpassed its competitor in dynamic characteristics, and its combat range was 200 kilometers longer than the F-100.

Such circumstances led to increased interest in Soviet developments on the part of the Americans, and after the end of the Korean War, officer No Geum Seok stole a MiG-19 from a Soviet airbase, providing it to the United States, for which he received a reward of $100,000.

Civil supersonic aviation

The technical developments obtained during the wars gave impetus to the rapid development of aviation in the 60s. The main problems caused by breaking the sound barrier were solved, and designers were able to begin designing the first supersonic civil aircraft.

The first supersonic airliner designed to carry passengers flew in 1961. This aircraft was a Douglas DC-8, piloted without passengers, with ballast placed on board to simulate their weight for testing in conditions as close to real as possible. At the time of descent from a height of 15877, the speed was 1262 km/h.

Also, the speed of sound was unplannedly exceeded by a Boeing 747 when the plane, en route from Taipei to Los Angeles, went into an uncontrolled dive as a result of malfunction and incompetence of the crew. Diving from an altitude of 125,000 meters to 2,900 meters, the plane exceeded the speed of sound, sustaining damage to the tail and causing serious injuries to two passengers. The incident occurred in 1985.

In total, two aircraft were built that were capable of truly exceeding the speed of sound in regular flights. They were the Soviet Tu-144 and the Anglo-French Aérospatiale-BAC Concorde. Apart from these aircraft, no other passenger aircraft could maintain supersonic cruising speed.

Tu-144 and Concorde

The Tu-144 is rightfully considered the first supersonic passenger aircraft in history, because it was built before the Concorde. These airliners were distinguished not only by excellent technical characteristics, but also by an elegant appearance - many consider them the most beautiful aircraft in the history of aviation.

Unfortunately, the Tu-144 became not only the first supersonic passenger aircraft to take to the skies, but also the first airliner of this type to crash. In 1973, 14 people died during a crash at Le Bourget, which served as the first impetus for the cessation of flights on this machine.

The second Tu-144 crash occurred in the Moscow region in 1978 - a fire broke out on the plane, causing the landing to be fatal for two crew members.

During the inspection, it was determined that the cause of the fire was a defect in the fuel system of the new engine, which was being tested at that time, but otherwise the aircraft showed excellent performance, as it was able to land when it caught fire. Despite this, commercial rail service on it was discontinued.

Concorde served European aviation much longer - flights on it lasted from 1976 to 2003. However, in 2000, this liner also crashed. While taking off from Charles De Gaulle, the plane caught fire and crashed to the ground, killing 113 people.

In the entire history of flights, Concorde never began to pay off, and after the disaster, the flow of passengers decreased so much that the project became even more unprofitable, and three years later flights on this supersonic aircraft ceased.

Technical characteristics of Tu-144

Many people wonder what the speed of a supersonic aircraft was? Let's look at the technical characteristics of the aircraft, which has long been the pride of domestic aviation:

Crew – 4 people;
Capacity – 150 people;
The ratio of length and height is 67/12.5 meters;
Maximum weight – 180 tons;
Thrust with afterburner – 17500 kg/s;
Cruising speed -2200 km/h;
Maximum height flight - 18,000 meters;
Flight range – 6500 kilometers.

Bell X-1

Source: NASA

North American X-15

Source: NASA

Lockheed SR-71 Blackbird

It would be a sin not to use supersonic aircraft for military purposes. Therefore, the US Air Force designed the Lockheed SR-71 Blackbird, a strategic reconnaissance aircraft with a maximum speed of 3,700 km/h (Mach number 3.5). The main advantages are fast acceleration and high maneuverability, which allowed it to evade missiles. The SR-71 was also the first aircraft to be equipped with radar signature reduction technologies.

Only 32 units were built, 12 of which crashed. In 1998 it was withdrawn from service.

Source: af.mil

MiG-25

Source: Alexey Beltyukov

MiG-31

The MiG-31 is designed to intercept and destroy air targets at extremely low, low, medium and high altitudes, day and night, in simple and adverse weather conditions, with active and passive radar interference, as well as false thermal targets. Four MiG-31s can control airspace up to 900 kilometers long. This is not an airplane, but the pride of the Union, which is still in service with Russia and Kazakhstan.

Source: Vitaly Kuzmin

Lockheed/Boeing F-22 Raptor

Source: af.mil

Su-100/T-4

The Su-100/T-4 (“weaving”) was developed as an aircraft carrier fighter. But the engineers of the Sukhoi Design Bureau managed not only to achieve their goal, but to simulate a cool strike and reconnaissance bomber-missile carrier, which they later even wanted to use as a passenger aircraft and booster for the Spiral aerospace system. The maximum speed of the T-4 is 3200 km/h (Mach 3).

A typical passenger plane flies at a speed of about 900 km/h. A military fighter jet can reach approximately three times the speed. However, modern engineers from the Russian Federation and other countries of the world are actively developing even more fast cars- hypersonic aircraft. What are the specifics of the relevant concepts?

Criteria for a hypersonic aircraft

What is a hypersonic aircraft? This is usually understood as a device capable of flying at a speed many times higher than that of sound. Researchers' approaches to determining its specific indicator vary. A common methodology is that an aircraft should be considered hypersonic if it is a multiple of the speed indicators of the fastest modern supersonic vehicles. Which are about 3-4 thousand km/h. That is, a hypersonic aircraft, if you adhere to this methodology, should reach a speed of 6 thousand km/h.

Unmanned and controlled vehicles

The approaches of researchers may also differ in terms of determining the criteria for classifying a particular device as an aircraft. There is a version that only those machines that are controlled by a person can be classified as such. There is a point of view according to which an unmanned vehicle can also be considered an aircraft. Therefore, some analysts classify machines of this type into those that are subject to human control and those that function autonomously. Such a division may be justified, since unmanned vehicles can have much more impressive technical characteristics, for example, in terms of overload and speed.

At the same time, many researchers consider hypersonic aircraft as a single concept, for which the key indicator is speed. It doesn’t matter whether a person sits at the helm of the device or the machine is controlled by a robot - the main thing is that the plane is fast enough.

Take off - independently or with outside help?

There is a widespread classification of hypersonic aircraft, which is based on classifying them into the category of those that are capable of taking off on their own, or those that require placement on a more powerful carrier - a rocket or a cargo plane. There is a point of view according to which it is legitimate to classify as devices of the type under consideration mainly those that are capable of taking off independently or with minimal involvement of other types of equipment. However, those researchers who believe that the main criterion characterizing a hypersonic aircraft, speed, should be paramount in any classification. Whether the device is classified as unmanned, controllable, capable of taking off on its own or with the help of other machines - if the corresponding indicator reaches the above values, then it means that we are talking about a hypersonic aircraft.

Main problems of hypersonic solutions

The concepts of hypersonic solutions are many decades old. Throughout the years of development of the corresponding type of devices, world engineers have been solving a number of significant problems that objectively prevent the production of “hypersonics” from being put into production - similar to organizing the production of turboprop aircraft.

The main difficulty in designing hypersonic aircraft is creating an engine that can be sufficiently energy efficient. Another problem is lining up the necessary apparatus. The fact is that the speed of a hypersonic aircraft in the values that we discussed above implies strong heating of the body due to friction with the atmosphere.

Today we will look at several examples of successful prototypes of aircraft of the corresponding type, the developers of which were able to make significant progress in successfully solving the noted problems. Let us now study the most famous world developments in terms of creating hypersonic aircraft of the type in question.

from Boeing

The fastest hypersonic aircraft in the world, according to some experts, is the American Boeing X-43A. Thus, during testing of this device, it was recorded that it reached speeds exceeding 11 thousand km/h. That is approximately 9.6 times faster

What's so special about the X-43A hypersonic aircraft? The characteristics of this aircraft are as follows:

The maximum speed recorded in tests is 11,230 km/h;

Wingspan - 1.5 m;

Body length - 3.6 m;

Engine - direct-flow, Supersonic Combustion Ramjet;

Fuel - atmospheric oxygen, hydrogen.

It can be noted that the device in question is one of the most environmentally friendly. The fact is that the fuel used practically does not emit harmful combustion products.

The X-43A hypersonic aircraft was developed jointly by NASA engineers, as well as Orbical Science Corporation and Minocraft. was created about 10 years ago. About $250 million was invested in its development. The conceptual novelty of the aircraft in question is that it was conceived with the aim of testing the latest technology for providing propulsion.

Development from Orbital Science

The Orbital Science company, which, as we noted above, took part in the creation of the X-43A, also managed to create its own hypersonic aircraft - the X-34.

Its top speed is more than 12 thousand km/h. True, during practical tests it was not achieved - moreover, it was not possible to achieve the indicator shown by the X43-A aircraft. The aircraft in question is accelerated when the Pegasus rocket, which operates on solid fuel, is activated. The X-34 was first tested in 2001. The aircraft in question is significantly larger than the Boeing aircraft - its length is 17.78 m, its wingspan is 8.85 m. The maximum flight altitude of the hypersonic vehicle from Orbical Science is 75 kilometers.

Aircraft from North American

Another famous hypersonic aircraft is the X-15, produced by North American. Analysts classify this apparatus as experimental.

It is equipped, which gives some experts a reason not to classify it, in fact, as an aircraft. However, the presence of rocket engines allows the device, in particular, to perform So, during one of the tests in this mode, it was tested by pilots. The purpose of the X-15 device is to study the specifics of hypersonic flights, evaluate certain design solutions, new materials, and control features of such machines in various layers of the atmosphere. It is noteworthy that it was approved back in 1954. The X-15 flies at a speed of more than 7 thousand km/hour. Its flight range is more than 500 km, its altitude exceeds 100 km.

The fastest production aircraft

The hypersonic vehicles we studied above actually belong to the research category. It will be useful to consider some production models of aircraft that are close in characteristics to hypersonic ones or are (according to one methodology or another) hypersonic ones.

Among such machines is the American development of the SR-71. Some researchers are not inclined to classify this aircraft as hypersonic, since its maximum speed is about 3.7 thousand km/h. Among its most notable characteristics is its take-off weight, which exceeds 77 tons. The length of the device is more than 23 m, the wingspan is more than 13 m.

The Russian MiG-25 is considered one of the fastest military aircraft. The device can reach speeds of more than 3.3 thousand km/h. Maximum take-off weight Russian plane- 41 tons.

Thus, in the market for serial solutions with characteristics close to hypersonic ones, the Russian Federation is among the leaders. But what can be said about Russian developments regarding “classic” hypersonic aircraft? Are engineers from the Russian Federation capable of creating a solution that is competitive with machines from Boeing and Orbital Scence?

Russian hypersonic vehicles

At the moment, the Russian hypersonic aircraft is under development. But it is going quite actively. We are talking about the Yu-71 aircraft. Its first tests, judging by media reports, were carried out in February 2015 near Orenburg.

It is assumed that the aircraft will be used for military purposes. Thus, a hypersonic vehicle will be able, if necessary, to deliver destructive weapons over considerable distances, monitor the territory, and also be used as an element of attack aircraft. Some researchers believe that in 2020-2025. The Strategic Missile Forces will receive about 20 aircraft of the corresponding type.

There is information in the media that the Russian hypersonic aircraft in question will be mounted on the Sarmat ballistic missile, which is also at the design stage. Some analysts believe that the Yu-71 hypersonic vehicle being developed is nothing more than a warhead that will have to be separated from the ballistic missile at the final stage of flight, and then, thanks to the high maneuverability characteristic of the aircraft, overcome missile defense systems.

Project "Ajax"

Among the most notable projects related to the development of hypersonic aircraft is Ajax. Let's study it in more detail. The Ajax hypersonic aircraft is a conceptual development of Soviet engineers. In the scientific community, conversations about it began back in the 80s. Among the most notable characteristics is the presence of a thermal protection system, which is designed to protect the case from overheating. Thus, the developers of the Ajax apparatus proposed a solution to one of the “hypersonic” problems we identified above.

The traditional thermal protection scheme for aircraft involves the placement of special materials on the body. The Ajax developers proposed a different concept, according to which it was not supposed to protect the device from external heat, but to let heat inside the machine, while simultaneously increasing its energy resource. The main competitor of the Soviet aircraft was considered to be the hypersonic aircraft “Aurora”, created in the USA. However, due to the fact that designers from the USSR significantly expanded the capabilities of the concept, new development was assigned a wide range of tasks, in particular research ones. We can say that the Ajax is a hypersonic multi-purpose aircraft.

Let's take a closer look at the technological innovations proposed by engineers from the USSR.

So, the Soviet developers of Ajax proposed using the heat generated as a result of friction of the aircraft body with the atmosphere and converting it into useful energy. Technically, this could be realized by placing additional shells on the device. As a result, something like a second corps was formed. Its cavity was supposed to be filled with some kind of catalyst, for example, a mixture of flammable material and water. The heat-insulating layer made of solid material in Ajax was supposed to be replaced with a liquid one, which, on the one hand, was supposed to protect the engine, on the other hand, would promote a catalytic reaction, which, meanwhile, could be accompanied by an endothermic effect - the movement of heat from the outside body parts inward. Theoretically, the cooling of the external parts of the device could be anything. The excess heat, in turn, was supposed to be used to increase the efficiency of the aircraft engine. At the same time, this technology would make it possible to generate free hydrogen as a result of the reaction of the fuel.

At the moment, there is no information available to the general public about the continued development of Ajax, but researchers consider the implementation of Soviet concepts into practice to be very promising.

Chinese hypersonic vehicles

China is becoming a competitor to Russia and the United States in the hypersonic solutions market. Among the most famous developments of engineers from China is the WU-14 aircraft. It is a hypersonic controlled glider mounted on a ballistic missile.

An ICBM launches an aircraft into space, from where the vehicle sharply dives down, developing hypersonic speed. The Chinese device can be mounted on various ICBMs with a range from 2 to 12 thousand km. It was found that during tests, the WU-14 was able to reach a speed exceeding 12 thousand km/h, thus becoming the fastest hypersonic aircraft according to some analysts.

At the same time, many researchers believe that it is not entirely legitimate to classify the Chinese development as an aircraft. Thus, there is a widespread version according to which the device should be classified specifically as a warhead. And very effective. When flying downward at the specified speed, even the most modern missile defense systems will not be able to guarantee interception of the corresponding target.

It can be noted that Russia and the United States are also developing hypersonic vehicles used for military purposes. At the same time, the Russian concept, according to which it is supposed to create machines of the appropriate type, differs significantly, as evidenced by data in some media, from the technological principles implemented by the Americans and the Chinese. Thus, developers from the Russian Federation are concentrating their efforts in the field of creating aircraft equipped with a ramjet engine that can be launched from the ground. Russia plans to cooperate in this direction with India. Hypersonic vehicles created according to the Russian concept, according to some analysts, are characterized by lower cost and a wider range of applications.

At the same time, the Russian hypersonic aircraft, which we mentioned above (Yu-71), suggests, as some analysts believe, deployment on ICBMs. If this thesis turns out to be correct, then we can say that engineers from the Russian Federation are working simultaneously in two popular conceptual directions in the construction of hypersonic aircraft.

Summary

So, probably the fastest hypersonic aircraft in the world, if we talk about aircraft regardless of their classification, is still the Chinese WU-14. Although you need to understand that real information about it, including those related to tests, may be classified. This is quite consistent with the principles of Chinese developers, who often strive to keep their military technologies secret at all costs. The speed of the fastest hypersonic aircraft is more than 12 thousand km/h. The American development of the X-43A is “catching up” with it - many experts consider it to be the fastest. Theoretically, the hypersonic aircraft X-43A, as well as the Chinese WU-14, can catch up with the development from Orbical Science, designed for a speed of more than 12 thousand km/h.

The characteristics of the Russian Yu-71 aircraft are not yet known to the general public. It is quite possible that they will be close to the parameters of the Chinese aircraft. Russian engineers are also developing a hypersonic aircraft capable of taking off independently, rather than based on an ICBM.

Current projects of researchers from Russia, China and the United States are in one way or another related to the military sphere. Hypersonic aircraft, regardless of their possible classification, are considered primarily as carriers of weapons, most likely nuclear. However, in the works of researchers from different countries of the world, there are theses that “hypersonic”, like nuclear technologies, may well be peaceful.

The issue is the emergence of affordable and reliable solutions that make it possible to organize mass production of machines of the appropriate type. The use of such devices is possible in the widest range of sectors of economic development. Hypersonics are in greatest demand aircrafts are likely to be found in the space and exploration industries.

As production technologies for the corresponding vehicles become cheaper, transport businesses may begin to show interest in investing in such projects. Industrial corporations and providers of various services may begin to consider “hypersonic” as a tool for increasing business competitiveness in terms of organizing international communications.