1.46 Pascals is exerted on the board.
The First!
Thanks for the clarification in the discussion. First: you don't really want force. The force is measured in newtons, and is the same whether you drop the hammer only a short distance or from the roof of the highest building you can get to. You really want to know the kinetic energy, which will be measured in joules, since that's what depends on the height. So: enough blather. How do you find these things? The easiest way is to weigh the sledgehammer. If you've got a scale that shows newtons, congratulations. If not, but you can find one that shows kilograms, then just multiply the mass of the hammer in kilograms by the acceleration due to gravity (9.8 meters per second per second) to find newtons. Suppose your sledgehammer has a mass of 4.0 kg. Multiply by 9.8 m/s/s to get 39 N. Once you know the force acting on the hammer, you can use that to calculate the kinetic energy. That's just the force in newtons multiplied by the height (in meters) you drop the hammer from. To make it simple, let's suppose it's being dropped from 1.0 meter. The force is then 39 N * 1.0 m = 39 J.
A diamond can shatter if hit with a hammer. While diamond is the hardest naturally-occurring mineral known, it is also brittle. The hardness means that it is difficult to cut, but the brittleness means that it is likely to splinter or shatter if enough pressure is exerted. In the case of a diamond hit with a hammer, the likelihood that the diamond will shatter will increase with the force of the hammer (based mostly on the weight) and will further increase if the diamond has any significant inclusions (indicated by a flaw in the diamond). Given the value of a diamond, it is highly recommended that you do not try this at home.
when you raise the hammer at the top of your upswing the hammer has potential energy when you lower the hammer to hit a nail , the hammer has potential energy.
A hammer would hit the ground first because a hammer is heavier
The First!
In 1843-- steam raised the hammer, but the weight of the hammer was the only pressure used to shape the metal. By 1888, a double-acting hammer used steam to supplement the pressure exerted by the falling hammer.
The hammer is acting as a lever. The force exerted against the fulcrum (the head of the hammer) causes the claw end to lift and extract the nail.
change the direction of force,because it exerted the force on it.
Pounding a nail into a board with a hammer in terms of matter energy and force is best described by inertia force.
The men's hammer weighs 16 lb (7.257 kg) and measures 4 feet (122 cm) in length and the women's hammer weighs 8.82 lb (4 kg) and 4 feet (122 cm) in length.
Hammer, tape measures, knife, chissels, level, screwdrivers and a nail set.
Thanks for the clarification in the discussion. First: you don't really want force. The force is measured in newtons, and is the same whether you drop the hammer only a short distance or from the roof of the highest building you can get to. You really want to know the kinetic energy, which will be measured in joules, since that's what depends on the height. So: enough blather. How do you find these things? The easiest way is to weigh the sledgehammer. If you've got a scale that shows newtons, congratulations. If not, but you can find one that shows kilograms, then just multiply the mass of the hammer in kilograms by the acceleration due to gravity (9.8 meters per second per second) to find newtons. Suppose your sledgehammer has a mass of 4.0 kg. Multiply by 9.8 m/s/s to get 39 N. Once you know the force acting on the hammer, you can use that to calculate the kinetic energy. That's just the force in newtons multiplied by the height (in meters) you drop the hammer from. To make it simple, let's suppose it's being dropped from 1.0 meter. The force is then 39 N * 1.0 m = 39 J.
A diamond can shatter if hit with a hammer. While diamond is the hardest naturally-occurring mineral known, it is also brittle. The hardness means that it is difficult to cut, but the brittleness means that it is likely to splinter or shatter if enough pressure is exerted. In the case of a diamond hit with a hammer, the likelihood that the diamond will shatter will increase with the force of the hammer (based mostly on the weight) and will further increase if the diamond has any significant inclusions (indicated by a flaw in the diamond). Given the value of a diamond, it is highly recommended that you do not try this at home.
Claw Hammer Sledge hammer Ball peen hammer Framing Hammer Mallet hammer Framing Hammer Upholstery hammer Geologist's hammer
An object in motion stays in motion until acted upon by an outside force. When the energy from the hammer hits the nail the hammer stops because its acted on by the nail. The nail takes on most of the energy and goes into whatever you might be nailing, like wood. The nail stops and the wood takes the energy and it just keeps going until the energy stops.
hammer