Kursgesat forgets to mention the incredible forces that would put on the payload.
NASA funded a study that suggested they start with a jet going mach 10, or 3.5 km/s.
The fastest a person has ever gone is mach 6.7 or 2.02km/s.
For efficiency sake, you’d want to get up to speed in a reasonable amount of time.
I doubt humans can effectively use sky hooks.
Could be really good for stuff though
NASA funded a study that suggested they start with a jet going mach 10, or 3.5 km/s. The fastest a person has ever gone is mach 6.7 or 2.02km/s.
In a jet. In a rocket, just the ISS is going at >7km/s, so obviously it’s routine. A (scram)jet would be nicer from a fuel point of view, but you don’t need it. In any case, to get to double the velocity with the same acceleration, you just accelerate twice as long - space is always big enough for a pure rocket-type craft (beamed power or gun-type are a different matter).
When it comes to the skyhooks themselves, the study you’re thinking of gave a spread of different accelerations for the designs, from <1 G to quite heavy (but manageable for a trained professional).
The fastest a person has ever gone is mach 6.7 or 2.02km/s.
Astronauts on the ISS are currently zipping along at at 7.67 km/s just fine. The issue is acceleration, not speed. Tethers rotate fairly slowly, so the acceleration should be less than that of a rocket launch.
Kursgesat forgets to mention the incredible forces that would put on the payload. NASA funded a study that suggested they start with a jet going mach 10, or 3.5 km/s. The fastest a person has ever gone is mach 6.7 or 2.02km/s. For efficiency sake, you’d want to get up to speed in a reasonable amount of time. I doubt humans can effectively use sky hooks. Could be really good for stuff though
In a jet. In a rocket, just the ISS is going at >7km/s, so obviously it’s routine. A (scram)jet would be nicer from a fuel point of view, but you don’t need it. In any case, to get to double the velocity with the same acceleration, you just accelerate twice as long - space is always big enough for a pure rocket-type craft (beamed power or gun-type are a different matter).
When it comes to the skyhooks themselves, the study you’re thinking of gave a spread of different accelerations for the designs, from <1 G to quite heavy (but manageable for a trained professional).
Astronauts on the ISS are currently zipping along at at 7.67 km/s just fine. The issue is acceleration, not speed. Tethers rotate fairly slowly, so the acceleration should be less than that of a rocket launch.
And we’ve all been zipping around the sun at 29.78 km/s since each of our inceptions.