Free Body Diagrams Free Body Diagrams Principles of EngineeringTM

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Free Body Diagrams Free Body Diagrams Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Free Body Diagrams

Free Body Diagram Free Body Diagrams Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Visual representation of force and object interactions Individual objects or members are isolated from their environment or system, illustrating all external forces acting upon them Every object exists surrounded by other objects, perhaps resting against something, perhaps moving through its surroundings. While an object is in a given environment, it interacts with other objects around it, exerting forces on those objects and having forces exerted upon it. A free body diagram isolates an object from its environment, or system, and symbolically examines all of the forces acting on the object. This allows engineers to focus on the forces acting upon the object. From the free body diagram, engineers develop equations which can describe equilibrium, motion, momentum, strength, and many other physical properties.

Free Body Diagram Components Free Body Diagrams Free Body Diagram Components Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Force A straight line push or pull acting upon an object Vector quantity has direction and magnitude Direction is illustrated by arrowhead Magnitude is illustrated by length of line segment and is the amount of push or pull

Free Body Diagram Components Free Body Diagrams Free Body Diagram Components Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Moment The twisting effort about a point or axis when a force is applied at a distance Arc with an arrowhead acting about a point indicating direction of CW or CCW

Moment Review Moment (M) = Force (F) x distance (d) Free Body Diagrams Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Moment (M) = Force (F) x distance (d) Distance (d) is called the moment arm. It must be measured perpendicular to the line of action of the force. Point of Rotation F d Line of Action

Free Body Diagram Procedure Free Body Diagrams Free Body Diagram Procedure Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics A stack of three books, each weighing 5 lb, is sitting on top of a table. Draw the Free Body Diagram (FBD) of the top book.

Free Body Diagram Procedure Free Body Diagrams Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics 1. Sketch the isolated object. What is the isolated object? Top Book Free body diagrams should be drawn completely isolated from all other objects. We “free” the body from its system. Instead of taking time to draw the object in detail, we substitute a simple geometric shape, such as a square or a circle. For these exercises the shape we draw is considered dimensionless.

Free Body Diagram Procedure Free Body Diagrams Free Body Diagram Procedure Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics 2. Sketch the applied and norm forces. When an object is in contact with and is supported by a second object, the second object can be replaced with a normal force which is perpendicular to the surface of the second object. Free body diagrams should be drawn completely isolated from all other objects. We “free” the body from its system. Instead of taking time to draw the object in detail, we substitute a simple geometric shape, such as a square or a circle. For these exercises the shape we draw is considered dimensionless.

Free Body Diagram Procedure Free Body Diagrams Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics 2. Sketch the applied force and norm forces. Normal Force Reaction force pushing up on the book, causing it not to fall Free body diagrams should be drawn completely isolated from all other objects. We “free” the body from its system. Instead of taking time to draw the object in detail, we substitute a simple geometric shape, such as a square or a circle. For these exercises the shape we draw is considered dimensionless. Applied Force Weight of top book

Free Body Diagram Procedure Free Body Diagrams Free Body Diagram Procedure Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics 3. Label objects and forces. N=5 lbf PLTW – DE book Free body diagrams should be drawn completely isolated from all other objects. We “free” the body from its system. Instead of taking time to draw the object in detail, we substitute a simple geometric shape, such as a square or a circle. For these exercises the shape we draw is considered dimensionless. Ask the question: Why are these two forces equal? A typical answer would be that they are not moving. Go a little bit further and ask what law of motion explains this situation. Answer=Newton’s Second Law, which is F=ma. If there is no acceleration, then there is no net force. W=5 lbf

Free Body Diagram Procedure Free Body Diagrams Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics 4. Label dimensions. For more complex free body diagrams, proper dimensioning is required, including length, height, and angles. N=5 lbf 45° 8 ft 10 ft 38.6° PLTW – DE book Free body diagrams should be drawn completely isolated from all other objects. We “free” the body from its system. Instead of taking time to draw the object in detail, we substitute a simple geometric shape, such as a square or a circle. For these exercises the shape we draw is considered dimensionless. W=5 lbf

Free Body Diagram Practice Free Body Diagrams Free Body Diagram Practice Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Create a FBD for the sled pictured below. Fapp Fapp θ FN θ Ff W Ff W FN

Free Body Diagram Practice Free Body Diagrams Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Create a FBD for the refrigerator pictured below. FN Fapp Fapp W W Ff θ FN Ff θ

Free Body Diagram Practice Free Body Diagrams Free Body Diagram Practice Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Create a FBD for the pulley system pictured below. FT FBD of Mass 1: W1 FT FT FBD of the movable pulley: Free body diagrams are frequently used while solving pulley system problems. It is useful to isolate the parts of a pulley system to discover relationships between the parts. This pulley system consists of an upper fixed pulley, which is supporting block M1, and a lower movable pulley. The movable pulley is supporting block M2. A single rope or cord connects these pulleys. Both pulleys are considered mass-less and frictionless. A free body diagram of M1 would start with a small shape. Two forces are acting on M1: The weight of M1 and the tension force of the rope. We can also isolate the pulleys. Looking at the lower movable pulley, we draw the free body. The weight of the block M2 is pulling down on the pulley. Two strands of the rope are pulling up on the pulley, and each of the strands is exerting a tension force. The tension force in the rope is equal in each free body diagram within the system since there is a single tension force in the entire rope. W2 + W pulley M2 M1 Tension Forces (FT ) are equal throughout the system.

Free Body Diagram Reactions Free Body Diagrams Free Body Diagram Reactions Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Different types of support reactions Cable, rope, or chain Pin Roller Built-in end – Cantilever To aid in completing free body diagrams, connections are often identified with letters.

Cable Support Cable, rope, chain – Replace with a tension force only. Free Body Diagrams Cable Support Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Cable, rope, chain – Replace with a tension force only.

Free Body Diagrams Cable Support Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics A sign with weight W is hung by two cables as shown. Draw the FBD of the sign and cables.

Cable Support FBD of sign and cables Free Body Diagrams Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics FBD of sign and cables

Free Body Diagrams Pin Support Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Pin – Replaced with TWO reaction forces, one vertical (y) and one horizontal (x). Joint / Pin A Reaction Force x-direction A A RAx Joint / Pin A y-direction RAy Reaction Force

Free Body Diagrams Roller Support Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Roller – Replaced with ONE reaction force, perpendicular to surface A A Joint / Roller A y-direction RAy Reaction Force

Common Support Reactions Free Body Diagrams Common Support Reactions Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Beams and truss bridges are usually supported with one pin support and one roller support. This is called a simply supported object. Create a FBD for the simply supported beam. A B RAx RAy RBy

Free Body Diagrams Built-In-End Support Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Built-in-end (cantilever) – Replaced with TWO forces: one horizontal and one vertical, and ONE moment Create a FBD for the built-in-end cantilever. A MAccw RAx RAy

Summary Support Reactions Free Body Diagrams Summary Support Reactions Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Contact – Replace with a normal force Cable, rope, chain – Replace with tension force Pin – Replace with two reaction forces; one vertical and one horizontal Roller – Replace with one reaction force perpendicular to surface Built-in-end (cantilever) – Replace with one horizontal force, one vertical force, and one moment

Free Body Diagrams Truss Bridge FBD Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics Supported with a pin at one end and a roller at the other Draw the FBD of the entire truss bridge. A B C D E 500 lb

Truss Bridge FBD FBD of the entire truss bridge B C D E 500 lbf RAx Free Body Diagrams Truss Bridge FBD Principles of EngineeringTM Unit 4 – Lesson 4.1 - Statics FBD of the entire truss bridge B C D E 500 lbf RAx RAy RCy