P2.3 - Forces in Action

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iqra

Cards (33)

Plastic deformation is when an object is distorted and cannot revert back to its original shape when forces are removed.
Elastic deformation is when an object is distorted but can revert back to its original shape once forces are removed.
Hooke's law explains that force and extension have a linear relationship up to a certain point. This point is known as the limit of proportionality.
Below an object's elastic limit, it can revert back to its original shape once a force is removed. Above this limit, and it cannot.
Force on a spring (N) = spring constant (N/m) * extension (m)
The gradient of a linear graph of force against extension is the spring constant.
The spring constant tells you how stiff the spring is, or how difficult it is to to stretch.
Energy transferred in stretching (J) = 0.5 * spring constant (N/m) * extension $^2$
An elastic band has a non-linear relationship between a force and its extension.
As you blow up a balloon, at first it is difficult. But as the balloon stretches more to hold more air, it becomes easier. Eventually, it becomes stiff again.
A gravitational field is a region where a mass experiences an attractive force.
Gravity force (N) = mass (kg) * gravitational field strength (N/kg)
Gravitational field strength (or gravity constant) is a measure of force on 1 kg of mass when it is in a gravitational field due to another mass.
Mass does not change, but the force of the mass relies on the field.
The force between a mass in a gravitational field and the mass with the field can be bigger if:
The mass of one or both objects are big.
The distance is small.
Weight (N) = mass (kg) * gravitational field strength (N/kg)
The gravitational field strength of the earth is 10 N/kg.
Resultant force (N) = mass (kg) * acceleration due to gravity (m/s $^2$ )
Gravitational potential energy is the energy needed to lift an object in a gravitational field.
gravitational potential energy (J) = mass (kg) * height (m) * gravitational field strength (N/kg)
A lever is a force multiplier that transmits forces by rotating around a pivot.
The effort is the force exerted on a lever.
The load is the force a lever exerts onto an object.
If the pivot is close to the load, little effort is required. Pushing down on the lever produces a turning force, but your hand moves further than the load.
The ratio of the load to the effort is known as the mechanical advantage:
mechanical advantage = load / effort
Gears are like levers that rotate. A small cog can exert a force onto a larger cog but it has to move further than if the larger cog exerted the force onto the smaller cog. In this case, the larger cog would use a bigger force to move the smaller cog.
The ratio between the diameters of cogs tells you the ratio of effort to load.
Gears can be used to change direction in which the rotating force acts, or the speed at which it rotates.
Inclined planes reduces the force needed to lift certain objects.
Pressure produces forces at right angles to any surface.
Pressure (Pa) = force normal on the surface (N) / surface area (m $^2$ )
Hydraulic machines use liquids to exert forces as it is almost impossible to compress them.
A simple hydraulic machine is made of two pistons and a pipe with a liquid inside it. When one piston moves, it moves a liquid inside the pipe which pushes the other piston. A small force is required to push the other piston, this makes hydraulic machines force multipliers.