no force, it has momentum
foot-pound. That is the application of one pound(al) of force to an object with a lever at 1 foot distance from the point of application. Usually, a torque wrench is used to apply a specific force to a bolt, measured in foot-pounds.
Inertia coinsides (excuse me for my spelling if there are any mistakes!) with Newton's 1st Lqaw. So say the quarterback for the football team is running straight for the goal poast, if the object ( Qb) is in motion it will stay in motion unless acted upon by an unbalanced force(Some 500 pound guy from the opposite team), it will remain at rest. ( A quarterback is going to kick a ball that was a rest. The Qb's kick is the unbalanced force.) <<<<ARK>>>> Inertia coinsides (excuse me for my spelling if there are any mistakes!) with Newton's 1st Lqaw. So say the quarterback for the football team is running straight for the goal poast, if the object ( Qb) is in motion it will stay in motion unless acted upon by an unbalanced force(Some 500 pound guy from the opposite team), it will remain at rest. ( A quarterback is going to kick a ball that was a rest. The Qb's kick is the unbalanced force.) <<<<ARK>>>> Inertia coinsides (excuse me for my spelling if there are any mistakes!) with Newton's 1st Lqaw. So say the quarterback for the football team is running straight for the goal poast, if the object ( Qb) is in motion it will stay in motion unless acted upon by an unbalanced force(Some 500 pound guy from the opposite team), it will remain at rest. ( A quarterback is going to kick a ball that was a rest. The Qb's kick is the unbalanced force.) <<<<ARK>>>>
It is not a question of how many magnets you need, one would do; but how strong the field is and how strongly it attracts the 400 pound object.
The top of a CO2 canister isn't very thick. It will take about a half a pound of pressure to break through the top.
A pound of any substance, material or "stuff" weighs the same as a pound of anything else. A pound is a pound, whether it's cotton or nails.
Depends on the magnitude and direction of the force applied to stop it.
Any force that is more than 50 pounds will lift a 50-pound object. The greater the force is, the greater the object's upward acceleration, and the sooner the object will reach any given height.
A one pound force applied in a pulling fashion on an object.
The net force on a 7 pound object that is falling (accelerating down) is 7 pounds. If it is not falling or moving at a constant speed, it is zero.
Any unit of force that appeals to you.The "pound-force" (usually called simply the "pound") and the "newton" are the most popular. Note: The "gram" and the "kilogram" are NOT units of force.
25 newtons
The question cannot be answered sensibly because a pound is a measure of mass which is not the same as weight. The weight of an object depends on the force of gravity acting o it and that force depends on the position of the object and other masses near it.
A 150 pound resultant force
foot-pound. That is the application of one pound(al) of force to an object with a lever at 1 foot distance from the point of application. Usually, a torque wrench is used to apply a specific force to a bolt, measured in foot-pounds.
2.5 hours to lose 1 pound. You must be going at least 7 miles an hour
First, see the LINK below to learn what a foot-pound is, then read as follows: So as you can see, you cannot convert pounds to foot pounds. The magnitude of a torque is equal to the magnitude of the applied force multiplied by the distance between the object's axis of rotation and the point where the force is applied. That means that one foot-pound of torque is a force of one pound applied one foot from the object's axis of rotation. So if the weight were one foot from the axis, you could say that one foot-pound is equal to one pound. But... Only if the weight was perpendicular to the line from the axis to where the weight was located. Torque is a "turning" force and weight is a "linear" force. Hope that was helpful.
The slug is the unit of mass in the US common system of units, where the pound is the unit of force. The pound is therefore the unit of weight since weight is defined as the force of gravity on an object. While the pound force and pound weight are the widely used units for commerce in the United States, their use is strongly discouraged in scientific work. The standard units for most of scientific work are the SI units.