Free body diagram

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File:Free body diagram2.svg
Block on a ramp and corresponding free body diagram of the block.

In physics a free body diagram (force diagram,[1] or FBD) is a graphical illustration used to visualize the applied forces, movements, and resulting reactions on a body in a steady state condition (no acceleration of the system). They depict a body or connected bodies with all of the applied forces and moments, as well as reactions, that act on that/those body(ies). The body may consist of multiple internal members, for example, a truss, or be a compact body such as a beam. A series of free bodies and other diagrams may be necessary to solve complex problems.

Purpose

Free body diagrams are used to visualize the forces and moments applied to a body and calculate the resulting reactions, in many types of mechanics problems. Most free body diagrams are used both to determine the loading of individual structural components as well as calculating internal forces within the structure in almost all engineering disciplines from Biomechanics to Structural.[2][3] In the educational environment, learning to draw a free body diagram is an important step in understanding certain topics in physics, such as statics, dynamics and other forms of classical mechanics. One professor at Cornell University earned the nickname "Free-Body Perkins" because of his passion for teaching the importance of using free body diagrams to solve mechanics problems.[4] He went so far as to stop random students in the hall, saying, “You! Come in my office! Draw a free body diagram!”[2]:80

Features

A free body diagram is not meant to be a scaled drawing. It is a diagram that is modified as the problem is solved. There is an art and flexibility to the process. The iconography of a free body diagram, not only how it is drawn but also how it is interpreted, depends upon how a body is modeled.[5]

Free body diagrams consist of:

  • A simplified version of the body (often a dot or a box)
  • Forces shown as straight arrows pointing in the direction they act on the body
  • Moments shown as curved arrows pointing in the direction they act on the body
  • A coordinate system
  • Frequently reaction to applied forces are shown with hash marks through the stem of the arrow

The number of forces and moments shown in a free body diagram depends on the specific problem and the assumptions made; common assumptions are neglecting air resistance, friction and assuming rigid bodies. In statics all forces and moments must balance to zero; the physical interpretation of this is that if the forces and moments do not sum to zero the body is in motion and the principles of statics do not apply. T In dynamics the resultant forces and moments can be non-zero.

Free body diagrams may not represent an entire physical body. Using what is known as a "cut" only portions of a body are selected for modeling. This technique exposes internal forces, making them external, therefore allowing analysis. This technique is often used several times, iteratively to peel back forces acting on a physical body. For example, a gymnast performing the iron cross: analyzing the ropes and the person lets you know the total force (body weight, neglecting rope weight, breezes, buoyancy, electrostatics, relativity, rotation of the earth, etc..). Then cut the person out and only show one rope. You get force direction. Then only look at the person, now you can get hand forces. Now only look at the arm to get the shoulder forces and moments, and on and on until the component you intend to analyze is exposed.

Modeling the body

A body may be modeled in three ways:

  • a particle. This model may be used when any rotational effects are zero or have no interest even though the body itself may be extended. The body may be represented by a small symbolic blob and the diagram reduces to a set of concurrent arrows. A force on a particle is a bound vector.
  • rigid extended. Stresses and strains are of no interest but turning effects are. A force arrow should lie along the line of force, but where along the line is irrelevant. A force on an extended rigid body is a sliding vector.
  • non-rigid extended. The point of application of a force becomes crucial and has to be indicated on the diagram. A force on a non-rigid body is a bound vector. Some use the tail of the arrow to indicate the point of application. Others use the tip.

Example: A body in free fall

File:Empty rigid bucket.svg
Figure 2: An empty rigid bucket in free fall in a uniform gravitational field with the force arrow at the center of gravity.

Consider a body in free fall in a uniform gravitational field. The body may be

  • a particle. It is enough to show a single vertically downward pointing arrow attached to a blob.
  • rigid extended. A single arrow suffices to represent the weight W even though gravitational attraction acts on every particle of the body.
  • non-rigid extended. In non-rigid analysis, it would be an error to associate a single point of application with the gravitational force.

What is included

An FBD represents the body of interest and the external forces on it.

  • The body: This is usually sketched in a schematic way depending on the body - particle/extended, rigid/non-rigid - and on what questions are to be answered. Thus if rotation of the body and torque is in consideration, an indication of size and shape of the body is needed. For example, the brake dive of a motorcycle cannot be found from a single point, and a sketch with finite dimensions is required.
  • The external forces: These are indicated by labelled arrows. In a fully solved problem, a force arrow is capable of indicating
    • the direction and the line of action[notes 1]
    • the magnitude
    • the point of application.
    • a reaction as opposed to an applied load if a hash is present through the arrow

Typically, however, a provisional free body sketch is drawn before all these things are known. After all, the whole point of the diagram is to help to determine magnitude, direction, and point of application of the external loads! Thus when a force arrow is originally drawn its length may not be meant to indicate the unknown magnitude. Its line may not correspond to the exact line of action. Even its direction may turn out to be wrong. Very often the original direction of the arrow may be directly opposite to the true direction. External forces known to be small that are known to have negligible effect on the result of the analysis, are sometimes omitted, but only after careful consideration or after other analysis proving it (e.g. buoyancy forces of the air in the analysis of a chair, or atmospheric pressure on the analysis of a frying pan).

The external; forces acting on the object include friction, gravity, normal force, drag, tension, or a human force due to pushing or pulling. When in a non-inertial reference frame (see [coordinate system[, below), fictitious forces, such as centrifugal pseudoforce are appropriate.

A coordinate system is sometimes included, and is chosen according to convenience (or advantage). Savvy selection of coordinate frame may make defining the vectors simpler when writing the equations of motion. The x direction might be chosen to point down the ramp in an inclined plane problem, for example. In that case the friction force only has an x component, and the normal force only has a y component. The force of gravity will still have components in both the x and y direction: mgsin(θ) in the x and mgcos(θ) in the y, where θ is the angle between the ramp and the horizontal.

Exclusions

There are some things that a free body diagram explicitly excludes. Although other sketches that include these things may be helpful in visualizing a problem, a proper free body diagram should not show:

  • Bodies other than the free body.
  • Constraints.
    • (The body is not free from constraints; the constraints have just been replaced by the forces and moments that they exert on the body.)
  • Forces exerted by the free body.
    • (A diagram showing the forces exerted both on and by a body is likely to be confusing since all the forces will cancel out. By Newton's 3rd law if body A exerts a force on body B then B exerts an equal and opposite force on A. This should not be confused with the equal and opposite forces that are necessary to hold a body in equilibrium.)
  • Internal forces.
    • (For example, if an entire truss is being analyzed, the forces between the individual truss members are not included.)
  • Velocity or acceleration vectors.

Analysis

A free body diagram is analyzed by summing all of the forces, often accomplished by summing the forces in each of the axis directions. When the net force is zero the body must be at rest or some constant velocity, by Newton's first law. If the net force is not zero then the body is accelerating in that direction, by Newton's second law.

Angled forces

File:Vector components.JPG
Angled force (F) broken down into horizontal (Fx) and vertical (Fy) components

Determining the sum of the forces is straightforward if all they are aligned with the coordinate frame's axes, but it is somewhat more complex if some forces are not aligned. It is often convenient to analyze the components of the forces, in which case the symbols ΣFx and ΣFy are used instead of ΣF. Forces that point at an angle to the diagram's coordinate axis can be broken down into two parts (or three, for three dimensional problems)—each part being directed along one of the axes—horizontally (Fx) and vertically (Fy).

Example: A block on an inclined plane

A simple free body diagram, shown above, of a block on a ramp illustrates this.

  • All external supports and structures have been replaced by the forces they generate. These include:
    • mg: the product of the mass of the block and the constant of gravitation acceleration: its weight.
    • N: the normal force of the ramp.
    • Ff: the friction force of the ramp.
  • The force vectors show direction and point of application and are labeled with their magnitude.
  • It contains a coordinate system that can be used when describing the vectors.

Some care is needed in interpreting the diagram. The line of action of the normal force has been shown to be at the midpoint of the base but its true location can only be found if sufficient further data is given. The diagram as it stands would need to be modified were we told that the block is in equilibrium.

There is a potential difficulty also with the arrow representing friction. The engineer who drew this diagram has used the tip of the arrow to indicate the point of application of a force. (See the other force arrows in the diagram). Now, the tip of the friction arrow is at the highest point of the base. The intention however is not to indicate that the friction acts at that point. The engineer in this instance has assumed a rigid body scenario and that the friction force is a sliding vector and thus the point of application is not relevant. The engineer has tried to indicate that the friction acts all along the whole base by drawing an arrow all along the base but such artistic ploys are a matter of personal choice.

See also

References

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Notes

  1. The line of action is important where moment matters
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