Turtles are purple and thier are no exeptions for hoe purple a Turtle really is and I hope the answer was a lifesaving if not . . . you are some trash and a hue dingos. singed,
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Tonald Drump
There is a mechanical advantage in using a long, gently sloping ramp than a short steep ramp. If you want to test this remember what goes up must come down and a long ramp gives you more time to react
The height of the Great Pyramid = 139 metres The slope of a ramp with a mechanical advantage of 4 = 4x139 = 556m
A very practical example of mechanical advantage is the use of a "cheater bar." If you find a bolt that is hard to break, simply slip a long pipe or similar object over the handle and it will apply much more torque.
6
1 Watt = 1 N-m . s^-1 Thus, assuming no acceleration while moving the object upward (exclude the situation of moving it from rest), then we get: 1334N * 4m = 5336 N-m X s * 1000 N-m . s^-1 = 5336 N-m So, X = 5.336 seconds
The ideal mechanical advantage of the bar is 5.
The mechanical advantage is 8/2 = 4.
There is a mechanical advantage in using a long, gently sloping ramp than a short steep ramp. If you want to test this remember what goes up must come down and a long ramp gives you more time to react
A very practical example of mechanical advantage is the use of a "cheater bar." If you find a bolt that is hard to break, simply slip a long pipe or similar object over the handle and it will apply much more torque.
a long and fat knife
The height of the Great Pyramid = 139 metres The slope of a ramp with a mechanical advantage of 4 = 4x139 = 556m
The height of the Great Pyramid = 139 metres The slope of a ramp with a mechanical advantage of 4 = 4x139 = 556m
The height of the great pyramid = 139 metres The slope of a ramp with a mechanical advantage of 4 = 4x139 = 556m
a long wedge has a greater mechanical energy then a short wide wedge.
1). First of all, in order to make an object rise at all, an upward force must be applied to it, and the force must be greater than the object's weight. 2). If an upward force exactly equal to the object's weight is applied to it, then the object can "hover" wherever you put it, as if it is weightless, but it can't rise. 3). If the upward force is greater than the object's weight, then the object can rise to any desired height. It will continue to rise, and its speed will increase, as long as the upward force continues. 4). When the upward force stops, then the object will continue to rise, but it's upward speed will begin to decrease. When the upward speed decreases to zero, the object stops rising and begins to fall. It's downward speed then increases continually, until it hits the ground.
The mechanical advantage is a numerical relationship among the sizes of physical components of the machine. It's constant as long as the sizes of those parts of the machine are constant.
3.3 ft