The biggest reason for flying at higher altitudes lies in fuel efficiency. The thin air creates less drag on the aircraft, which means the plane can use less fuel in order to maintain speed.
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In the case of gasoline engines, the higher altitude theoretically leads to lower fuel consumption due to lower throttle frictions due to the wider throttle opening. From the other side, as the air is less dense at higher altitudes, the vehicle aerodynamic is changed and this also leads to lower fuel consumption.
Fuel dumping (or a fuel jettison) is a procedure used by aircraft in certain emergency situations before a return to the airport shortly after takeoff, or before landing short of the intended destination (emergency landing) to reduce the aircraft's weight.
Simply add the strength of the headwind (30 mph) to your best glide speed (78 mph) and you've got the most efficient speed to fly—here, 108 mph. To determine an airplane's Carson speed, multiply its best glide speed by 1.32. This will get the best result in terms of true airspeed and fuel consumption.
Air density decreases with altitude, thus lowering drag, assuming the aircraft maintains a constant equivalent airspeed. However, air pressure and temperature both decrease with altitude, causing the maximum power or thrust of aircraft engines to reduce.
Higher Altitude Means Less PowerGenerally speaking, an engine loses three percent of its rated power for every 1,000 feet of altitude gained. This means you could lose as much as 20% of your vehicle's horsepower if you drive it from sea level to Big Bear Lake (with its 6,750 elevation).
For Part 91 General Aviation operations the required flight crew must use supplemental oxygen for any portion of the flight that exceeds 30 minutes above a cabin pressure altitude of 12,500 feet mean sea level (MSL) up to and including 14,000 feet (MSL).
Higher Altitude Means Less PowerGenerally speaking, an engine loses three percent of its rated power for every 1,000 feet of altitude gained. This means you could lose as much as 20% of your vehicle's horsepower if you drive it from sea level to Big Bear Lake (with its 6,750 elevation).
The reason planes cruise at high altitudes is that they burn less fuel and can fly faster, as the air is less dense. At 30,000 feet and higher, it is also possible for aircraft to avoid weather systems, making it more comfortable onboard.
Because the Earth is a three-dimensional sphere and not merely a two-dimensional flat, East-West surface. Because of this spherical shape, often times the shortest distance is flying more north and south, up over the Northern latitudes and the North Pole, rather than flying east/west over the Pacific.
Commercial jets, however, have more sensors and control measures to prevent midair collisions, meaning they generally aren't affected by traffic. Private jets lack the high-tech sensors and controls of commercial jets, so pilots operating them typically fly at a higher altitude where there's less traffic.
The reason planes cruise at high altitudes is that they burn less fuel and can fly faster, as the air is less dense. At 30,000 feet and higher, it is also possible for aircraft to avoid weather systems, making it more comfortable onboard.
The flight measure- ments indicate that for the higher altitudes (40,000 to 75,000 ft), turbulence is both less fre- quent and less severe than for the lower altitudes (20,000 to 40,000 ft). Turbulence appears to be present at the high altitudes less than 1% of the time.
The reduced takeoff thrust procedure increases engine durability, lowers maintenance costs, and increases engine reliability. The airliners we have today are highly overpowered as they are designed to safely take off with one engine inoperative.
Airplanes are fast and efficient because they can operate in a low friction environment. There are no wheels (at least in flight) that have to be constantly be rolled over the ground, and at higher altitude the air is thinner which reduces air drag dramatically.
Technically this is the so-called 'stall speed', where air passes over the wings fast enough to sustain altitude, and for small planes this can be less than 50km/h (31mph). But at such low speeds, the aircraft is easily destabilised, and could fail to leave the runway.