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all fo the muscles are recruited to add more force to your throw
more length more torque, force applied remains the same
The general idea is that the escape velocity from Earth is 11.2 km/second. This assumes there is no atmosphere. I guess "thrust" would be expressed in units of force; the force can be just about anything, from just slightly bit more than the object's weight (to counter Earth's gravity), to a lot more, depending how long the force is applied. In other words, if you apply more force, you need to apply the force for less time to achieve escape velocity.
to apply less force while doing more work on an object
YES!!! Assuming the acceleration() is constant. Then F = Ma & f= ma If M > m then F(force) > f(force)
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Hockey. Pucks were invented for ice hockey, and if it hadn't developed, more people would simply play field hockey (the original way of playing hockey).
You can apply alot more force with the help of air pressure
all fo the muscles are recruited to add more force to your throw
I would say hockey, but I'm not entirely sure.
more length more torque, force applied remains the same
The actual force may be the same, but a screwdriver with a large HANDLE can be more effective in applying that force. You can grip it and apply force easier.
The Brake Booster increases the force applied to the brake lever so that the brake disc or drum recieves more force. Without it the brakes would be much harder to apply.
You don't
The general idea is that the escape velocity from Earth is 11.2 km/second. This assumes there is no atmosphere. I guess "thrust" would be expressed in units of force; the force can be just about anything, from just slightly bit more than the object's weight (to counter Earth's gravity), to a lot more, depending how long the force is applied. In other words, if you apply more force, you need to apply the force for less time to achieve escape velocity.
to apply less force while doing more work on an object
true