3.1 What is a Rigid Body? . Figure 3 – 1: An interesting Rigid Body. Figure 3 – 2: A lever is a simple rigid body. This chapter deals with rigid body statics problems. As a starting point, this section discusses the differences between a particle and a rigid body and how these differences affect the problem solving process. There are an infinite number of combinations of F and P that satisfy Eq. (3 – 1), each of which maintains the lever in translational equilibrium. Although translational equilibrium is satisfied, the lever is not necessarily balanced. For example, when no force F is applied, the solution F = 0, P = 100 lb satisfies Eq. (3 – 1) yet the system is clearly unbalanced. The problem is that rotational equilibrium has not been satisfied. Degrees-of-Freedom Consider the lever shown in Fig. 3 – 2. Assume that a resistance force of R =100 lb acts on the right end of the lever b = 1 ft from fulcrum A. A downward force F is applied on the other end of the lever a = 2 ft from the fulcrum to keep the lever in equilibrium. The equilibrium of the lever is maintained by the applied force F and an upward force P at the fulcrum. Let’s first regard the lever as a particle and then as a rigid body. In order to maintain the lever in rotational equilibrium, an additional relationship is needed. The additional relationship is When the lever is regarded as a particle, the three forces can be thought of as acting concurrently (See Figure 3 – 3). Translational equilibrium in the vertical direction is maintained by setting the resultant force in the vertical direction to zero, that is In ancient times, Eq. (3 – 2) was known as the Law of the Lever. You’ll see in Example 3 – 1 and later in Section 3.4 that Eq. (3 – 2) follows from Newton’s First and Third Laws. After learning about moments, you’ll discover in Section 3.4 that Eq. (3 – 2) merely expresses the statement that the sum of the moments acting on the lever is zero. (3 – 1) (3 – 2) 0 = – R – F + P. aF = bR . Equation (3 – 1) is one equation expressed in terms of the two unknown forces F and P (Recall that R is known). Figure 3 – 3: Freebody diagram of a lever treated as a particle Chapter Objectives Section 3.1 What is a Rigid Body? 3.2 Moments in a Plane 3.3 Moments in Space 3.4 Equilibrium of a Rigid Body 3.5 Equivalent Systems 3.6 System Behavior Figure 3 – 4: Free-body diagram of a lever treated as a rigid body Objective To describe the type of engineering problem commonly referred to as a rigid body problem To become proficient at mathematically manipulating moments in a plane To become proficient at mathematically manipulating moments in space To show how to solve rigid body problems in space To show how to reduce complexity through the use of equivalent systems To describe the different types of behavior of static systems 1 Equation (3 – 1) is the governing equation associated with the translational degree-of-freedom in the vertical direction. Equation (3 – 2) is the governing equation associated with the rotational degree-of-freedom about the z axis (perpendicular to the x-y plane). Substituting Eq. (3 – 2) into (3 – 1) yields b 1 R 100 50 lb, a 2 P R F 100 50 150 lb. F This solution maintains the lever in a state of equilibrium – both translational and rotational. In planar problems, like in the lever problem just discussed, there are generally three governing equations. Two of them are associated with the two translational degrees-of-freedom and one is associated with the rotational degree-of-freedom. (In the lever problem just discussed we didn’t need to look at translational equilibrium in the horizontal direction.) In the most general situation, when the forces lie in any of the three directions of space, there are six governing equations. Three of them are associated with the three translational degrees-of-freedom and the other three are associated with the three rotational degrees of freedom. The Set-up Step and the Transition Step In the transition step, where a word statement is converted into a mathematical statement, unimportant information is discarded, leaving only the information that is absolutely essential to the analysis. In this step, transition diagrams are drawn. The most important transition diagram is the free body diagram. To draw the free body diagrams of the rigid body in a system, the bodies in the system are cut away from each other. The influences that the surrounding bodies have on a given rigid body are replaced with forces and moments acting on the rigid body. The free-body diagram of a rigid body will differ from the free-body diagram of a particle in two significant ways. First, for a rigid body, the locations of the forces will be important whereas for a particle the Table 1: The Particle versus the Rigid Body Particle Mass is idealized to be located at a point. Forces are idealized to be located at a point. Forces maintain translational equilibrium. To maintain equilibrium, F = 0. Recall that the problem solving process begins with the set-up step and the transition step. In the set-up step the system is divided into bodies and each body is identified as either a particle or as a rigid body. Recall that the decision to regard the body as a particle or as a rigid body does not depend on the size of the body, as much as on what equilibrium conditions you want to impose. In general, there are six equilibrium conditions associated with the rigid body (three translational and three rotational), so up to six conditions can be imposed. If you impose only translational equilibrium conditions then the body is called a particle and the forces can be thought to act concurrently. If you impose any of the rotational equilibrium conditions then the locations of the forces become important and the body is called a rigid body. Rigid Body Size and shape of the body are influential. Locations of forces are important. Forces create moments acting on the body. Forces maintain translational and rotational equilibrium. To maintain equilibrium, F = 0, MA = 0. locations of the forces were not important. Secondly, the free-body diagram for a rigid body will contain moments (which have not yet been defined) whereas the free-body diagram of a particle did not contain moments. After the transition step, the governing equations are listed in the equation step, the equations are solved in the answer step, and finally an understanding of the behavior of the system is gained in the knowledge step. However, let’s not jump ahead of ourselves. We need to first understand what a moment is. The next two sections develop the moment. Key Terms Degree-of-Freedom, Law of the Lever, Lever, Moment, Rotational Equilibrium, Translational Equilibrium Review Questions 1. At most, how many degrees-of-freedom does a particle have? At most, how many degrees-of-freedom does a rigid body have? 2. When a body is regarded as a rigid body, is it important to know where on the body the forces are applied? 3. In what two ways does a free-body diagram of a rigid body differ from a free-body diagram of a particle? 4. State in words the Law of the Lever. 2