FREE BODY DIAGRAMS   4 Nickels awarded! Tagged with:  explanation     academic    posted on 17 Apr 2007 22:39:48 IST
No doubt you are aware of free body diagrams (otherwise known as FBD's). These are simplified representations of an object (the body) in a problem, and includes force vectors acting on the object. This body is free because the diagram will show it without its surroundings; i.e. the body is 'free' of its environment. This eliminates unnecessary information which might be given in a problem. Gravity Normal Force Friction Push or Pull Tension Figure 1 A ship, pulled by a rope, on a sunny day. (Use your imagination.) ----------------------------------------------------------------- Let's take Figure 1 to be a pictoral representation of our problem: a boat on the floor, with a rope pulling it. First we will represent the boat -- the 'body' in our problem -- as a (really) simplified figure, a square (Figure 2). Figure 2 Simplified diagram of the ship -------------------------------------------------------------------------------------------------------------------   Gravity The first force we will investigate is that due to gravity, and we'll call it the gravitational force. We know that the acceleration due to gravity (if on Earth) is approximately g = 9.8 m/s. The force, by Newton's Second Law is F = m g where g is the acceleration due to gravity. Let's add this to our diagram (Figure 3). Note that the force vector, labelled Fmg, points downward, as this is the direction in which the gravitation force acts. Note that this force is commonly called weight. This 'weight' (m g) is different from our everyday use of the word 'weight' (which is known in physics as 'mass'). Figure 3 Ship, with the gravitational force labelled -------------------------------------------------------------------------------------------------------------------   Normal The normal force one which prevents objects from 'falling' into whatever it is they are sitting upon. It is always perpendicular to the surface with which an object is in contact. For example, if there is a crate on the floor, then we say that the crate experiences a normal force by the floor; and because of this force, the crate does not fall into the floor. The normal force on the crate points upward, perpendicular to the floor. It is called the normal force because normal and perpendicular mean the same thing. The normal force is always perpendicular to the surface with which a body is in constact. For a body on a sloped surface (say a ramp), the normal force acting on that body is still perpendicular to the slope. In the case of our problem, the ship, we will pretend the ship is being pulled on a floor. (This is because on water there is the complication with another force, buoyancy. For simplicity's sake, we will ignore buoancy by putting the ship on the floor.) Let's add the normal force to our FBD (Figure 4), and represent the normal force with the script 'N', . Figure 4 Ship, with gravitational and normal forces. ------------------------------------------------------------------------------------------------------------------- Friction Related to the normal force is the frictional force. The two are related because they are both due to the surface in contact with the body. Whereas the normal force was perpendicular to the surface, the frictional force is parallel. Furthermore, friction opposes motion, and so its vector always points away from the direction of movement. Friction is divided into two categories, static and kinetic. These are represented by the script 'F', with a subscript 's' for static friction: , and a subscript 'k' for kinetic friction, . As its name suggests, static friction occurs when the body is not moving (i.e. "static"). It is the force which makes it difficult to start something moving. On the other hand, kinetic friction occurs when the body is in motion. This is the force which causes objects to slow down and eventually stop. Friction is usually approximated as being proportional to the normal force. The proportionality constant is called the coefficient of (static or kinetic) friction. The constant is represented as for static friction, and for kinetic friction; it depends on the actual surface with which the body is in contact. To summarize, = = We've added (kinetic) friction to our free body diagram, Figure 5. Figure 5 Ship, with gravitational, normal, and frictional forces Push and Pull Another force which may act on an object could be any physical push or pull. This could be caused by a person pushing a crate on the floor, a child pulling on a wagon, or in the case of our example, the wind pushing on the ship. We will label the push force caused by the wind with Fpush Figure 6 Ship, with gravitational, normal, frictional, and push forces Tension Tension in an object results if pulling force act on its ends, such as in a rope used to pull a boulder. If no forces are acting on the rope, say, except at its ends, and the rope itself is in equilibrium, then the tension is the same throughout the rope. We will use the letter T to represent tension in a free body diagram. If we say that our ship is being pulled by a rope at its front end, then we can add this force to our FBD (Figure 7). Figure 7 Ship with gravitational, normal, frictional, push, and tension forces And there we have it: all the forces acting on our ship has been labelled in Figure 7. This is the complete FBD for our problem of a ship being pulled along a floor by a rope.   Awaiting your comments   -Darshan	About the Author: mydarshankumar (2079) Blazing goIITian  379  [471 rates] total posts: 412     Offline
this article: 125 points  (with 23    in 28 votes )   [?]   You have to be logged on to rate
comment by karthik_abiram    (posted on 17 Apr 2007 22:56:31 IST) nice explanation........
comment by vinod    (posted on 17 Apr 2007 22:59:09 IST) awesome explanation with gr8 visuals...keep it up darshan!! v need such!! :)
comment by mastermind890    (posted on 17 Apr 2007 23:10:22 IST) Great work darshan!!!!!
comment by Jyothi    (posted on 18 Apr 2007 06:17:50 IST) NICE WORK ....DARSHAN.....
comment by siddharthsaxena    (posted on 18 Apr 2007 10:54:12 IST) this one was cool
comment by rshm15varma    (posted on 20 Apr 2007 16:25:11 IST) gud work
comment by SMARTY    (posted on 24 Apr 2007 12:26:30 IST) gr888888888888
comment by prodyumno_a24    (posted on 24 Apr 2007 15:10:36 IST) well done pal
comment by kprabhakar    (posted on 24 Apr 2007 19:26:51 IST) good work palll
comment by mydarshankumar    (posted on 9 Nov 2007 09:53:47 IST) PLS DO COMMESNTS MORE
comment by revathi_pearl    (posted on 13 Nov 2007 19:09:01 IST) awesum work !!!!.keep it up!!.. :)
comment by Mr.IITIAN007    (posted on 13 Nov 2007 19:34:14 IST) gr888888888888
comment by krithika.r    (posted on 14 Nov 2007 18:54:37 IST) i really liked it a lot
comment by anil_kapoor    (posted on 15 Nov 2007 10:46:29 IST) gud

1 2 ►  GO Go to Page...

Go to:  Select a forum   Physics   General   Mechanics   Optics   Thermal Physics   Electricity   Magnetism   Modern Physics   Mathematics   Algebra   Trignometry   Analytical Geometry   Differential Calculus   Integral Calculus   Vectors   Chemistry   Physical Chemistry   Organic Chemistry   Inorganic Chemistry   Biology - for AIPMT Appearing   Botany   Zoology   Institutes & Courses   Coaching Institutes & Course Material   About IITs and JEE   Non IIT Institutes   Counselling Zone   Parents Corner   Parent Discussion Board   Board Exams - CBSE, ICSE, State Boards   Course Material   Computer Science   Fun Zone   Lounge   Games, Puzzles and Quizzes   General Knowledge   Other Courses   GATE   Commerce Streams   Business Administration   Civil Services   Law Entrance   Banking Careers   Fashion designing   Computer Applications