Vector Mechanics For Engineers: Statics Twelfth Edition Copyright © 2020 McGraw Hill , All Rights Reserved. PROPRIETARY MATERIAL © 2020 The McGraw Hill Inc. All rights reserved. No part of this PowerPoint slide may be displayed, reproduced or distributed in any form or by any means, without the prior written permission of the publisher, or used beyond the limited distribution to teachers and educators permitted by McGraw Hill for their individual course preparation. If you are a student using this PowerPoint slide, you are using it without permission. Chapter 2 Statics of Particles Contents Application Sample Problem 2.3 Introduction Equilibrium of a Particle Forces on a Particle: Resultant of Two Forces Free-Body Diagrams and Problem Solving Vectors Sample Problem 2.4 Addition of Vectors Sample Problem 2.6 Resultant of Several Concurrent Forces Expressing a Vector in 3-D Space Sample Problem 2.1 Sample Problem 2.7 Sample Problem 2.2 Rectangular Components of a Force: Unit Vectors Addition of Forces by Summing X and Y Components © 2019 McGraw-Hill Education. Application The tension in the cable supporting this person can be found using the concepts in this chapter. © 2019 McGraw-Hill Education. @ Michael Doolittle/Alamy Introduction The objective for the current chapter is to investigate the effects of forces on particles: • replacing multiple forces acting on a particle with a single equivalent or resultant force, • relations between forces acting on a particle that is in a state of equilibrium. The focus on particles does not imply a restriction to miniscule bodies. Rather, the study is restricted to analyses in which the size and shape of the bodies is not significant to the problem under consideration, so that all forces may be assumed to be applied at a single point. © 2019 McGraw-Hill Education. Resultant of Two Forces • force: action of one body on another; characterized by its point of application, magnitude, line of action, and sense. • Experimental evidence shows that the combined effect of two forces may be represented by a single resultant force. • The resultant is equivalent to the diagonal of a parallelogram which contains the two forces in adjacent legs. • Force is a vector quantity. Access the text alternative for these images. © 2019 McGraw-Hill Education. Vectors Vectors: parameters possessing magnitude and direction that add according to the parallelogram law. Examples: forces, displacements, velocities, accelerations. Scalars: parameters possessing magnitude but not direction. Examples: mass, volume, temperature. Vector classifications: • Fixed or bound vectors have well defined points It states that the sum of the of application that cannot be changed without squares of the lengths of the affecting an analysis. four sides of a parallelogram equals the sum of the squares • Free vectors may be freely moved in space of the lengths of the two without changing their effect on an analysis. diagonals. • Sliding vectors may be applied anywhere along their line of action without affecting an analysis. © 2019 McGraw-Hill Education. Addition of Vectors • Parallelogram law for vector addition • Triangle rule for vector addition • Law of cosines, R 2 P 2 Q 2 2 PQ cos B R PQ • Law of sines (using figure (a) at left), sin A sin B sin C Q R P • Vector addition is commutative, PQ Q P • Vector subtraction Access the text alternative for these images. © 2019 McGraw-Hill Education. Resultant of Several Concurrent Forces • Concurrent forces: set of forces that all pass through the same point. A set of concurrent forces applied to a particle may be replaced by a single resultant force that is the vector sum of the applied forces. • Vector force components: two or more force vectors that, together, have the same effect as a single force vector. Access the text alternative for these images. © 2019 McGraw-Hill Education. Sample Problem 2.1 1 Strategy: • Graphical solution - construct a parallelogram with sides in the same direction as P and Q and lengths in proportion to these forces. Graphically evaluate the resultant that is equivalent in direction and proportional in magnitude to the diagonal. The two forces act on a bolt at A. Determine their resultant. • Trigonometric solution - use the triangle rule for vector addition in conjunction with the law of cosines and law of sines to find the resultant. Access the text alternative for these images. © 2019 McGraw-Hill Education. Sample Problem 2.1 2 Modeling and Analysis: • Graphical solution - A parallelogram with sides equal to P and Q is drawn to scale. The magnitude and direction of the resultant (the diagonal of the parallelogram) are measured, R 98 N 35 • Graphical solution - A triangle is drawn with P and Q head-to-tail and to scale. The magnitude and direction of the resultant (the third side of the triangle) are measured, R 98 N 35 Access the text alternative for these images. © 2019 McGraw-Hill Education. Sample Problem 2.1 3 • Trigonometric solution - Apply the triangle rule. From the Law of Cosines, R 2 P 2 Q 2 2 PQ cos B 40 N 60 N 2 40 N 60 N cos155 2 2 R 97.73N From the Law of Sines, sin A sin B Q 60N ; sin A sin B sin155 Q R R 97.73N A 15.04 20 A 35.04 Reflect and Think: An analytical solution using trigonometry provides for greater accuracy. However, it is helpful to use a graphical solution as a check. © 2019 McGraw-Hill Education. Sample Problem 2.2 1 Strategy: A barge is pulled by two tugboats. If the resultant of the forces exerted by the tugboats is 5000 lb directed along the axis of the barge, determine the tension in each of the ropes when = 45o. Discuss with a neighbor how you would solve this problem. © 2019 McGraw-Hill Education. • Find a graphical solution by applying the Parallelogram Law for vector addition. The parallelogram has sides in the directions of the two ropes and a diagonal in the direction of the barge axis and length proportional to 5000 lb. • Find a trigonometric solution by applying the Triangle Rule for vector addition. With the magnitude and direction of the resultant known and the directions of the other two sides parallel to the ropes given, apply the Law of Sines to find the rope tensions. Sample Problem 2.2 2 Modeling and Analysis: • Graphical solution - Parallelogram Law with known resultant direction and magnitude, and known directions for sides. T1 3700lb T2 2600lb • Trigonometric solution - Triangle Rule with Law of Sines T1 T2 5000lb sin45 sin30 sin105 T1 3660lb T2 2590lb Access the text alternative for these images. © 2019 McGraw-Hill Education. What if…? 1 • At what value of a would the tension in rope 2 be a minimum? Hint: Use the triangle rule and think about how changing α changes the magnitude of T2. After considering this, discuss your ideas with a neighbor. • The minimum tension in rope 2 occurs when T1 and T2 are perpendicular. T2 5000lbsin30 T2 2500lb T1 5000lbcos30 T1 4330lb 90 30 60 Reflect and Think: Part (a) is a straightforward application of resolving a vector into components. The key to part (b) is recognizing that the minimum value of T2 occurs when T1 and T2 are perpendicular. © 2019 McGraw-Hill Education. © 2019 McGraw-Hill Education. Rectangular Components of a Force: Unit Vectors • It’s possible to resolve a force vector into perpendicular components so that the resulting parallelogram is a rectangle. Fx and Fy are referred to as rectangular vector components and F Fx Fy • Define perpendicular unit vectors i and j that are parallel to the x and y axes. • Vector components can be expressed as products of the unit vectors with the scalar magnitudes of the vector components. F Fx i Fy j Fx and Fy are referred to as the scalar components of F © 2019 McGraw-Hill Education. Addition of Forces by Summing X and Y Components • To find the resultant of 3 (or more) concurrent forces, R PQS • Resolve each force into rectangular components, then add the components in each direction: Rx i Ry j Px i Py j Qx i Qy j S x i S y j Px Qx S x i Py Qy S y j • The scalar components of the resultant vector are equal to the sum of the corresponding scalar components of the given forces. Rx Px Qx S x Fx Ry Py Qy S y Fy • To find the resultant magnitude and direction, R Rx2 Ry2 © 2019 McGraw-Hill Education. tan 1 Ry Rx Sample Problem 2.3 1 Strategy: • Resolve each force into rectangular components. • Determine the components of the resultant by adding the corresponding force components in the x and y directions. Four forces act on bolt A as shown. Determine the resultant of the force on the bolt. • Calculate the magnitude and direction of the resultant. Access the text alternative for this image. © 2019 McGraw-Hill Education. Sample Problem 2.3 2 Analysis: • Resolve each force into rectangular components. Force mag x − comp F1 150 +129.9 +75.0 F2 80 −27.4 +75.2 F3 110 0 −110.0 F4 100 +96.6 −25.9 Rx 199.1 Ry 14.3 blank Reflect and Think: Arranging data in a table not only helps you keep track of the calculations, but also makes things simpler for using a calculator on similar computations. © 2019 McGraw-Hill Education. blank y − comp • Determine the components of the resultant by adding the corresponding force components. • Calculate the magnitude and direction. R 199.12 14.32 tan 14.3 N 199.1 N R 199.6N 4.1 © 2019 McGraw-Hill Education. Equilibrium of a Particle • When the resultant of all forces acting on a particle is zero, the particle is in equilibrium. • Newton’s First Law: If the resultant force on a particle is zero, the particle will remain at rest or will continue at constant speed in a straight line. Particle acted upon by two forces: • equal magnitude. • same line of action. • opposite sense. Particle acted upon by three or more forces: • graphical solution yields a closed polygon. • algebraic solution. R F 0 F x 0 F Access the text alternative for these images. © 2019 McGraw-Hill Education. y 0 Free-Body Diagrams and Problem Solving (a) Space diagram Space Diagram: A sketch showing the physical conditions of the problem, usually provided with the problem statement, or represented by the actual physical situation. © 2019 McGraw-Hill Education. (b) Free-body diagram Free Body Diagram: A sketch showing only the forces acting on the selected particle. This must be created by you. Sample Problem 2.4 1 Strategy: • Construct a free body diagram for the particle at the junction of the rope and cable. • Apply the conditions for equilibrium by creating a closed polygon from the forces applied to the particle. In a ship-unloading operation, a 3500-lb automobile is supported by a cable. A rope is tied to the cable and pulled to center the automobile over its intended position. What is the tension in the rope? © 2019 McGraw-Hill Education. • Apply trigonometric relations to determine the unknown force magnitudes. Sample Problem 2.4 2 Analysis: • Apply the conditions for equilibrium and solve for the unknown force magnitudes. Law of Sines: Modeling: T TAB 3500lb AC sin120 sin 2 sin 58 TAB 3570lb TAC 144lb Access the text alternative for these images. © 2019 McGraw-Hill Education. Sample Problem 2.4 3 Reflect and Think: This is a common problem of knowing one force in a three-force equilibrium problem and calculating the other forces from the given geometry. This basic type of problem will occur often as part of more complicated situations in this text. © 2019 McGraw-Hill Education. Sample Problem 2.6 1 Strategy: • Decide what the appropriate “body” is and draw a free body diagram. • The condition for equilibrium states that the sum of forces equals 0, or: It is desired to determine the drag force at a given speed on a prototype sailboat hull. A model is placed in a test channel and three cables are used to align its bow on the channel centerline. For a given speed, the tension is 40 lb in cable AB and 60 lb in cable AE. Determine the drag force exerted on the hull and the tension in cable AC. R F 0 F x F y 0 • The two equations means we can solve for, at most, two unknowns. Since there are 4 forces involved (tensions in 3 cables and the drag force), it is easier to resolve all forces into components and apply the equilibrium conditions Access the text alternative for this image. © 2019 McGraw-Hill Education. 0 Sample Problem 2.6 2 Modeling and Analysis: • The correct free body diagram is shown and the unknown angles are: 1.5 ft 7 ft tan 0.375 tan 1.75 4 ft 4 ft 20.56 60.25 • In vector form, the equilibrium condition requires that the resultant force (or the sum of all forces) be zero: R TAB TAC TAE FD 0 • Write each force vector above in component form. Access the text alternative for these images. © 2019 McGraw-Hill Education. Sample Problem 2.6 3 • Resolve the vector equilibrium equation into two component equations. Solve for the two unknown cable tensions. TAB 40 lb sin 60.26 i 40 lb cos 60.26 j 34.73 lb i 19.84 lb j TAC TAC sin 20.56 i TAC cos 20.56 j 0.3512 TAC i 0.9363TAC j TAE 60 lb j FD FD i R0 34.73 0.3512 TAC FD i 19.84 0.9363TAC 60 j © 2019 McGraw-Hill Education. Sample Problem 2.6 4 R0 34.73 0.3512 TAC FD i 19.84 0.9363TAC 60 j This equation is satisfied only if each component of the resultant is equal to zero F F x y 0 34.73 0.3512TAC FD 0 0 19.84 0.9363TAC 60 0 TAC 42.9 lb FD 19.66 lb Reflect and Think: In drawing the free-body diagram, you assumed a sense for each unknown force. A positive sign in the answer indicates that the assumed sense is correct. You can draw the complete force polygon (above) to check the results. © 2019 McGraw-Hill Education. Expressing a Vector in 3-D Space 1 If angles with some of the axes are given: • The vector F is contained in the plane OBAC. • Resolve F into horizontal and vertical components. Fy F cos y Fh F sin y • Resolve F into rectangular components. Fx Fh cos F sin y cos Fz Fh sin F sin y sin © 2019 McGraw-Hill Education. Expressing a Vector in 3-D Space 2 If the direction angles are given: • With the angles between F and the axes, Fx F cos x Fy F cos y Fz F cos z F Fx i Fy j Fz k F cos x i cos y j cos z k F cos x i cos y j cos z k • is a unit vector along the line of action of F and cos x ,cos y , and cos z are the direction cosines for F © 2019 McGraw-Hill Education. Expressing a Vector in 3-D Space 3 If two points on the line of action are given: Direction of the force is defined by the location of two points, M x1 , y1 , z1 and N x2 , y2 , z2 d vector joining M and N d xi d y j d z k d x x2 x1 d y y2 y1 d z z2 z1 F F 1 d xi d y j d z k d Fd y Fd x Fd z Fx Fy Fz d d d © 2019 McGraw-Hill Education. Sample Problem 2.7 1 Strategy: • Based on the relative locations of the points A and B, determine the unit vector pointing from A towards B. • Apply the unit vector to determine the components of the force acting on A. The tension in the guy wire is 2500 N. Determine: a) components Fx, Fy, Fz of the force acting on the bolt at A, • Noting that the components of the unit vector are the direction cosines for the vector, calculate the corresponding direction angles. b) the angles x, y, z defining the direction of the force (i.e., the direction angles) Access the text alternative for this image. © 2019 McGraw-Hill Education. Sample Problem 2.7 2 Modeling and Analysis: • Determine the unit vector pointing from A towards B. AB 40m i 80m j 30mk AB 40m 80m 30m 2 2 2 94.3 m 40 80 30 i j k 94.3 94.3 94.3 0.424i 0.848 j 0.318k • Determine the components of the force. F F 2500 N 0.424 i 0.848 j 0.318k 1060N i 2120 N j 795 N k © 2019 McGraw-Hill Education. Sample Problem 2.7 3 • Noting that the components of the unit vector are the direction cosines for the vector, calculate the corresponding angles. cos x i cos y j cos z k 0.424i 0.848 j 0.318k x 115.1 y 32.0 z 71.5 © 2019 McGraw-Hill Education. What if…? 2 • Since the force in the guy wire must be the same throughout its length, the force at B (and acting toward A) must be the same magnitude but opposite in direction to the force at A. FBA FAB 1060N i 2120 N j 795 N k What are the components of the force in the wire at point B? Can you find it without doing any calculations? Give this some thought and discuss this with a neighbor. © 2019 McGraw-Hill Education. Reflect and Think: It makes sense that, for a given geometry, only a certain set of components and angles characterize a given resultant force. The methods in this section allow you to translate back and forth between forces and geometry. © 2019 McGraw-Hill Education. End of Chapter 2 © 2019 McGraw-Hill Education.
