No, a plane cannot go to space. Planes are designed to fly through the Earth’s atmosphere and typically reach a maximum altitude of around 35,000 to 40,000 feet. To be considered space, the altitude would have to be at least 62 miles (100 km).
This is known as the Kármán line. To reach this altitude, a craft needs to be able to travel at a speed of at least 17,400 miles per hour (28,000 km/h) — much faster than the top speed of any plane. Therefore, while a plane is able to fly high above the Earth’s atmosphere, it is not able to reach space.
Is there a plane that can go into space?
Yes, there are planes that have been designed to enter space. One of the most well-known is the X-15, which was created by the US Air Force and NASA and first flew in 1959. X-15s were tested at the edges of space to see how the aircraft and its systems performed in the unique environment.
After a series of successful tests, the X-15 was officially declared to have “crossed” the threshold of space. Since then, other planes have been designed, such as the Virgin Galactic SpaceShipTwo and the Rocketplane XP, which are both designed to take passengers and/or commercial cargo into space and/or to suborbital flight.
Regardless, all of these planes are still yet to be proven in operation, as of 2021.
Is it possible to fly a plane into space?
Yes, it is possible to fly a plane into space. In fact, the first flight of a manned aircraft beyond Earth’s atmosphere was on May 5, 1961, when Soviet cosmonaut Yuri Gagarin piloted the Vostok 1 spacecraft.
Since then, many other planes have been flown into space including the Space Shuttle, which was flown by NASA astronauts more than 100 times between 1981 and 2011. There are also commercial companies, such as Virgin Galactic and Blue Origin, that are currently developing their own spacecrafts and plan to fly passengers to space in the future.
In order to fly a plane into space, the aircraft must be able to reach velocities of more than 5 miles per second (25,000 mph) and overcome Earth’s gravitational force. This requires advanced propulsion systems such as rockets, which create thrust by burning a combination of fuel and oxygen to accelerate the aircraft.
Many of today’s planes are also outfitted with wings and other aerodynamic components to assist in the flight to space. All of these components, when combined, enable a plane to fly into space and be able to maneuver and control itself in the absence of air resistance.
Why can’t fighter jets fly into space?
Fighter jets, like all other aircraft, need to generate lift to stay in the air. This is done by creating a pressure difference between the top and bottom of the wings, due to the shape of the wings and the engine thrust.
In order to generate this lift in the air, the jet needs air or another dense fluid to move over the wings. As fighter jets fly higher and higher, they eventually reach the upper limit of the Earth’s atmosphere, where the air pressure is too low to generate lift.
This is called the “edge of space” and is typically considered to be around 100,000 feet above the Earth’s surface or 30,000 meters.
Fighter jets are designed to fly within the atmosphere, not in space, so they cannot reach this height. Additionally, even if a fighter jet were able to reach this height, it would not be able to maintain its altitude in a vacuum because there would be no air pressure to generate lift.
As a result, fighter jets are not able to fly into space.
What would happen if you flew a plane into space?
If you flew a plane into space, the outcome would depend largely on the design of the plane as well as the conditions under which it was flying. Generally, a plane designed to fly in Earth’s atmosphere would not be able to reach the edge of space, as the lack of atmosphere would cause the plane to stall and then drop back towards the planet’s surface.
However, there have been some specialized planes capable of reaching the edges of space. These planes typically have extremely powerful engines, huge wingspans, and air-breathing engines that allow them to reach altitudes high enough to reach the edge of space.
In the event that such a plane was able to reach the edge of space, it would continue to climb until the air around it became too thin to provide lift. Eventually, the plane would reach its peak altitude, at which point the pilot would have to pivot the plane back towards the Earth’s atmosphere, in order to reach a safe landing.
It is also worth noting that flying a plane into space would be an extraordinarily dangerous endeavor. The lack of air pressure and oxygen would cause the plane to stall out and fall rapidly, requiring incredible precision from the pilot in order to return safely to the ground.
Additionally, the intense heat and G-forces from the journey could cause disastrous consequences for the plane and its occupants.
Can humans fly at Mach 10?
No, it is impossible for humans to fly at Mach 10. Mach 10 is equivalent to 12,236 km/h (7,608 mph) which is well beyond the speed of sound and would offer incredibly strong air resistance and wind drag – both of which would make it impossible for a human body to maintain flight.
Additionally, the effects of air pressure, temperature, and density on the human body would be deadly at such a speed. A journey at this speed would also require an aircraft that has been tested under very specific and dangerous conditions, and the experience of such an extreme flight would be too dangerous for humans.
Although it is theoretically possible to break the sound barrier in certain conditions, the human body is not capable of sustaining the extreme strain and conditions which come with achieving such a speed.
Did Tom Cruise go Mach 10?
No, Tom Cruise has not gone Mach 10. The Mach number is a measure of an object’s speed as a fraction of the speed of sound, which works out to about 761 mph. Thus far, official reports have not recorded Tom Cruise going close to this speed.
Tom Cruise has, however, achieved some impressive speeds in his lifetime. As the star of the iconic film franchise Mission: Impossible, Cruise is famous for doing many of his own stunts, including wild car chases and extravehicular activities (EVA).
In 2018, he flew a jet sporting a specialized contrail spike on the wings to collect data while filming one of the Mission: Impossible sequels. During this flight, Cruise achieved speeds of roughly 600 mph, well below Mach 10.
Can humans survive 10g?
No, humans cannot survive an acceleration of 10g. Acceleration, or g-force, is a measure of the changes in velocity over time. The maximum amount of gravitational force a human can support without any adverse effects is around 5 to 6g, although this may vary depending on the individual.
Anything more than that would cause the blood in the body to be forced towards the feet and cause a potentially fatal blackout due to a lack of oxygen to the brain. Additionally, the strain on the body would likely cause other serious issues such as broken bones, significant injury, and hyperventilation.
To put 10g into perspective, a skydiver reaches a maximum of 3g during free fall, while an F-16 aircraft flying at 9g experiences enough force to cause a pilot to become unconscious in just a few seconds.
In conclusion, humans cannot survive 10g of acceleration.
What is the fastest Mach a human can fly?
Currently, the fastest Mach a human can fly is approximately Mach 7, which is 4800 km/h or 2,983. 82 mph. This was achieved in October 1967 by USAF Major William J. Knight in an SR-71 Blackbird. This is the fastest flight ever achieved by a conventional wing-based aircraft and will likely remain the record for some time.
However, it is possible for humans to travel faster than this. Astronaut Scott Kelly flew a NASA space shuttle to a speed of Mach 25 in July 2015, which is 20,256 km/h or 12,540. 41 mph. This is the fastest anyone has ever traveled in an Earth-orbiting spacecraft.
In addition, when exiting the Earth’s atmosphere, the Apollo 10 astronauts reached a speed of Mach 36.24, which is 25,803 km/h or 16,048 mph and is the fastest speed ever achieved by humans.
Lastly, on June 30th, 2012, Felix Baumgartner reached a speed of 1342 km/h or 833.9 mph, which is approximately Mach 1.24. This is the fastest freefall ever achieved by a human being.
Can you survive Mach 10 ejection?
It is not impossible to survive being ejected from a craft at Mach 10, but it would be extremely difficult and highly unlikely. The force of the ejection and extreme aerodynamic forces as the human body travels through the air at such high speeds can cause shattering impact injuries.
Additionally, there are enormous g-forces associated with ejections at this speed, which can cause further trauma, loss of consciousness, or even death. Furthermore, if the altitude is low enough, the extreme temperatures experienced during the sudden deceleration of the body could cause skin burning and other severe conditions.
All of these factors mean the chances of surviving an ejection at Mach 10 would be extremely slim.
Can a body sustain Mach 10?
No, a body cannot sustain Mach 10, which is ten times the speed of sound. To reach such speeds would require an enormous amount of energy and heat, and the resulting acceleration forces would be too great for a physical body to survive.
While some aircrafts have been able to reach Mach 10 in a dive, they are specially designed for this purpose and use external energy sources, such as additional solid-rocket accelerants, to reach the speed.
Also, their airframes are extremely sturdy, incorporating superalloys and honeycomb structures that give additional strength, allowing for more stringent aerodynamic shapes. When maintainingMach 10 speeds, a craft must be constantly subjected to intense heat that would instantly kill any human.
As such, there is currently no form of propulsion or human-rate technology capable of supporting these speeds and therefore a body cannot sustain Mach 10.
What is the highest Mach ever reached?
The highest Mach ever reached is believed to be Mach 9. 68, achieved by the NASA X-43A scramjet in 2004. The X-43A was an unmanned hypersonic research aircraft powered by a supersonic combustion ramjet, or scramjet.
It was designed to study the practicality of an aircraft powered by a scramjet and to explore hypersonic flight. The X-43A flight took place over the Pacific Ocean and pave the way for future hypersonic research and flight.
During the flight, the X-43A sustained Mach 9. 68 for 10 seconds and hit a top speed of around 7,000 mph, or Mach 9. 68. This was the highest recorded speed ever achieved by an aircraft and marked a major breakthrough in aerospace exploration.
What Mach is the speed of light?
The speed of light, also known as the speed of a photon, is a physical constant that is defined as 299,792,458 meters per second (m/s) in vacuum. This is the same in all inertial frames of reference, meaning that the speed of light is the same regardless of the observer’s movement relative to its source.
As a result, it is the fundamental determinant of c, the speed of causality, which is the speed of change in the universe. It has been measured to be approximately 299,792,458 m/s with a measurement uncertainty of 4 parts per billion.
What is the most G’s ever pulled?
The most G’s ever pulled was an incredible 46. 2 G’s, achieved by British Royal Air Force (RAF) test pilot Peter Wishart in a modified English Electric Lightning F6 aircraft in 1963. To reach this incredible feat, the aircraft was fitted with two Supermarine Spey turbofan engines which provided the additional thrust needed to reach these incredible speeds.
To sustain the G-Force of 46. 2, Wishart had to wear a special, pressurized G-suit. The G-suit helps to drain the buildup of fluids from the legs and abdomen to keep oneself conscious and conscious at such high speeds.
Wishart was able to break eight different records, such as the fastest absolute speed of 1,017 mph and the highest Mach number record of 1. 7 which he reached at 60,000 feet. This record stands to this day and demonstrates the amazing feats that our pilots are capable of in the pursuit of pushing the boundaries of aviation!.
How cold is the space?
The temperature in space can vary drastically depending on a number of factors, such as the location, time of year, proximity to the sun and other nearby objects, and more. Generally, temperatures in space are extremely cold, ranging from -450°F (-268°C) to alternatively up to 250°F (121°C).
In the colder regions of deep space, the temperature can drop to nearly absolute zero (0 Kelvin, or -273°C). Being exposed to the vacuum of space and extreme cold temperatures presents a very difficult environment for life to survive.
