Free Body Diagrams and Vector Diagrams Forces Part
Free Body Diagrams and Vector Diagrams Forces (Part 1)
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Topics �Recap from ICT Package �Free Body Diagrams �Types of Component Forces
Recap from ICT Package – What is a Force? �A force is a push or a pull �A force is a vector �Force has both magnitude and direction �Unit force is Newtons (N)
Recap from ICT Package – Balanced & Unbalanced Forces �When a more than one force acts on a body at the same time, each individual force is called a component force �The total sum of all the component forces acting on an object is the resultant force �For any one object, there can be several component forces, but only be one resultant force. �Sometimes, resultant force is also called “net force”
Recap from ICT Package – Balanced & Unbalanced Forces �When there is no resultant force (or resultant force = 0), the object is said to be balanced �When there is a resultant force, the object is said to be unbalanced. �We will discuss more about balanced and unbalanced forces in this chapter, and later in chapter 5.
Free Body Diagrams �A free body diagram is a diagram used to describe the forces acting on an object �It only describes the forces acting on ONE single object, and not other objects connected to it �Forces are represented by arrows. Direction of arrow represents direction of force Length of arrow represents magnitude of force Each arrow must be labelled
Free Body Diagrams �Objects are typically represented either using a silhouette of the object itself, or a simplification thereof. �E. g. free-body diagram of a cow in free fall COW Gravitational Force (Weight)
Types of Component Forces �Forces can be classified into 2 broad categories: contact forces & long range forces. �Contact forces require an object to physically touch something else in order for the force to take effect �Non-contact do not require physical contact for the force to take effect
Types of Component Forces Contact Forces Normal Contact Force Friction Tension Non-Contact Forces Gravitational Force (Weight) Electric Force Magnetic Force Electromagnetic Force
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Gravitational Force �Weight is simply the gravitational force exerted by the Earth on an object �Formula: Gravitational Force = mg, m = mass of the object (which the force is exerting on) g = gravitational field strength. This is also identical to the acceleration due to free fall, which is 10 ms-2. �It is advisable to use “mg” instead of “W” or any other symbol to represent weight or gravitational force.
Gravitational Force �To draw gravitational force of a free body diagram, locate the center of gravity of the object (typically the center of the object) �Draw an arrow downwards (towards the center of the Earth) �Label the arrow “mg” mg
Normal Contact Force �Sometimes called “normal reaction force” �The normal contact force is the force objects exert on each other when they press each other �Normal contact force is always a push force �Usually represented by symbol “N” or “n” �“Normal” here refers to “perpendicular” �The direction of normal contact force is always perpendicular to the surface of contact
Normal Contact Force � To draw normal contact force on a free body diagram, locate the surface of contact � Draw a force originating from the middle of the contact surface, going perpendicular and away from the surface � Label the arrow “N” or “n” N N Object on the ground Object on an inclined surface
Tension �Tension is the force exerted by a taut string, rope, spring, etc. pulling on an object �Usually represented by symbol “T” �Tension is always a pull force �To draw tension in a free body diagram, locate the point where the string (for e. g. ) is pulling the object �Draw an arrow originating from that point, in the same direction as the string �Label the arrow “T”
Tension �Consider this scenario: Ball suspended from the ceiling with a string �Free Body Diagram of the ball: T mg
Tension �Consider this scenario: Object being pulled along the ground by a string N �Free Body Diagram: T mg
Friction �Friction is the contact force that opposes of tends to oppose motion between surfaces in contact �There is no symbol for friction. Either spell the word out in full, or use “Ffriction“ �To draw friction in a free body diagram, identify the contact surfaces, and draw an arrow parallel to the surfaces, in the direction which would oppose motion
Friction moving to the right �If an object is moving in one direction, friction acts in the opposite direction �If friction is holding up an object which would otherwise slide away, friction acts in the direction opposing the sliding Friction
Rules for Drawing FBDs �Step 1: draw the object first. Do NOT draw other objects connected to it �Step 2: identify the center of gravity, draw and label the mg of the object �Step 3: draw all other component forces. The length of the arrows should be proportional to the magnitude of the force. �Note: NEVER draw the resultant force on a Free Body Diagram!! If there is a need to indicate the resultant force, draw it outside the FBD.
Example �Draw the FBD of an object which is being pulled by a rope up a rough slope T N mg Friction
Recap �Force is a push or pull, unit: Newtons (N) �Force is a vector (magnitude & direction) �Free Body Diagrams �Types of Component Forces Gravitational Force (weight) Normal Contact Force Tension Friction
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