SOLUTION 8 1. a+ M B = 0; N A = 0. N A = kn = 16.5 kn. Ans. + c F y = 0; N B = 0

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1 8 1. The mine car and its contents have a total mass of 6 Mg and a center of gravity at G. If the coefficient of static friction between the wheels and the tracks is m s = 0.4 when the wheels are locked, find the normal force acting on the front wheels at B and the rear wheels at A when the brakes at both A and B are locked. Does the car move? 10 kn 0.9 m B G A 0.15 m Equations of Equilibrium: The normal reactions acting on the wheels at (A and B) are independent as to whether the wheels are locked or not. Hence, the normal reactions acting on the wheels are the same for both cases. 0.6 m 1.5 m a+ M B = 0; N A = 0 N A = kn = 16.5 kn + c F y = 0; N B = 0 N B = kn = 42.3 kn When both wheels at A and B are locked, then 1F A 2 max = m s N A = = kn and 1F B 2 max = m s N B = = kn. Since 1F A 2 max + F B max = kn 7 10 kn, the wheels do not slip. Thus, the mine car does not move.

2 8 2. Determine the maximum force P the connection can support so that no slipping occurs between the plates. There are four bolts used for the connection and each is tightened so that it is subjected to a tension of 4 kn. The coefficient of static friction between the plates is m s = 0.4. P 2 P 2 P Free-Body Diagram: The normal reaction acting on the contacting surface is equal to the sum total tension of the bolts. Thus, N = 4(4) kn = 16 kn. When the plate is on the verge of slipping, the magnitude of the friction force acting on each contact surface can be computed using the friction formula F = m s N = 0.4(16) kn. As indicated on the free-body diagram of the upper plate, F acts to the right since the plate has a tendency to move to the left. Equations of Equilibrium: : + F x = 0; 0.4(16) - P 2 = 0 p = 12.8 kn

3 8 3. If the coefficient of static friction at A is m s = 0.4 and the collar at B is smooth so it only exerts a horizontal force on the pipe, determine the minimum distance x so that the bracket can support the cylinder of any mass without slipping. Neglect the mass of the bracket. B 100 mm x C 200 mm A

4 8 4. If the coefficient of static friction at contacting surface between blocks A and B is m s, and that between block B and bottom is 2 m s, determine the inclination u at which the identical blocks, each of weight W, begin to slide. A B u 2μ s (2W cos θ) W sin θ = 0 sinθ 7μ s cosθ = 0 7μ s Fʹ= 2µ s Nʹ

5 8 5. The coefficients of static and kinetic friction between the drum and brake bar are m s = 0.4 and m k = 0.3, respectively. If M = 50 N # m and P = 85 N determine the horizontal and vertical components of reaction at the pin O. Neglect the weight and thickness of the brake.the drum has a mass of 25 kg. 300 mm B O M 700 mm 125 mm 500 mm P A..

6 8 6. The coefficient of static friction between the drum and brake bar is ms = 0.4. If the moment M = 35 N # m, determine the smallest force P that needs to be applied to the brake bar in order to prevent the drum from rotating. Also determine the corresponding horizontal and vertical components of reaction at pin O. Neglect the weight and thickness of the brake bar. The drum has a mass of 25 kg. P 300 mm B O M 700 mm 125 mm A 500 mm...

7 8 7. The block brake consists of a pin-connected lever and friction block at B. The coefficient of static friction between the wheel and the lever is ms = 0.3, and a torque of 5N# m is applied to the wheel. Determine if the brake can hold the wheel stationary when the force applied to the lever is (a) P = 30 N, (b) P = 70 N. 50 mm A 150 mm O B 5N m P 200 mm 400 mm To hold lever: a+ M O = 0; F B (0.15) - 5 = 0; F B = N Require N B = N 0.3 = N Lever, a+ M A = 0; P Reqd. (0.6) (0.2) (0.05) = 0 P Reqd. = 39.8 N a) P = 30 N N No b) P = 70 N N Yes

8 8 8. The block brake consists of a pin-connected lever and friction block at B. The coefficient of static friction between the wheel and the lever is ms = 0.3, and a torque of 5N# m is applied to the wheel. Determine if the brake can hold the wheel stationary when the force applied to the lever is (a) P = 30 N, (b) P = 70 N. 50 mm 5N m 150 mm O A B 200 mm 400 mm P To hold lever: a+ M O = 0; -F B (0.15) + 5 = 0; F B = N Require N B = N 0.3 = N Lever, a+ M A = 0; P Reqd. (0.6) (0.2) (0.05) = 0 P Reqd. = N a) P = 30 N N No b) P = 70 N N Yes

9 8 9. The uniform hoop of weight W is suspended from the peg at A and a horizontal force P is slowly applied at B. If the hoop begins to slip at A when the angle is determine the coefficient of static friction between the hoop and the peg. Given: 30 deg Solution: F x = 0; N A cos P N A sin 0 P cos sin N A F y = 0; N A sin W N A cos 0 W sin cos N A = 0; W P r r cos r sin 0 P1 cos W sin sin cos sin sin cos1 cos sin cos

10 8 10. The uniform hoop of weight W is suspended from the peg at A and a horizontal force P is slowly applied at B. If the coefficient of static friction between the hoop and peg is s, determine if it is possible for the hoop to reach an angle before the hoop begins to slip. Given: s deg Solution: F x = 0; N A cos P N A sin 0 P cos sin N A F y = 0; N A sin W N A cos 0 W sin cos N A = 0; W P r r cos r sin 0 P 1 cos W sin sin cos sin sin cos1 cos sin cos If s 0.20 < 0.27 then it is not possible to reach deg.

11 8 11. The fork lift has a weight W 1 and center of gravity at G. If the rear wheels are powered, whereas the front wheels are free to roll, determine the maximum number of crates, each of weight W 2 that the fork lift can push forward. The coefficient of static friction between the wheels and the ground is s and between each crate and the ground is ' s. Given: W 1 12kN W (9.81) N s 0.4 ' s 0.35 a 0.75m b 0.375m c 1.05m Solution: Fork lift: M B = 0; W 1 c N A ( b c) = 0 c N A W 1 N A 8.8 kn b c F x = 0; Crate: F y = 0; s N A P P = 0 s N A P 3.54 kn N c W 2 = 0 N c W 2 N c kn F x = 0; P' ' s N c = 0 P' ' s N c P' kn Thus P n n 6.87 n floor( n) n 6 P'

12 8 12. If a torque of M = 300 N # m is applied to the flywheel, determine the force that must be developed in the hydraulic cylinder CD to prevent the flywheel from rotating. The coefficient of static friction between the friction pad at B and the flywheel is m s = 0.4. D Free-BodyDiagram: First we will consider the equilibrium of the flywheel using the free-body diagram shown in Fig. a. Here, the frictional force F B must act to the left to produce the counterclockwise moment opposing the impending clockwise rotational motion caused by the 300 N # m couple moment. Since the wheel is required to be on the verge of slipping, then F B = m s N B = 0.4 N B. Subsequently, the free-body diagram of member ABC shown in Fig. b will be used to determine F CD. Equations of Equilibrium: We have C 0.6 m 30 B 60 mm 0.3 m M 300 Nm O 1 m A a+ M O = 0; Using this result, 0.4 N B (0.3) = 0 N B = 2500 N a+ M A = 0; F CD sin 30 (1.6) + 0.4(2500)(0.06) (1) = 0 F CD = 3050 N = 3.05 kn

13 8 13. The cam is subjected to a couple moment of 5N# m. Determine the minimum force P that should be applied to the follower in order to hold the cam in the position shown. The coefficient of static friction between the cam and the follower is m s = 0.4. The guide at A is smooth. P 10 mm A B 60 mm O 5N m Cam: a+ M O = 0; N B (0.06) (N B ) = 0 N B = N Follower: + c F y = 0; P = 0 P = 147 N

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15 8 15. The car has a mass of 1.6 Mg and center of mass at G. If the coefficient of static friction between the shoulder of the road and the tires is m s = 0.4, determine the greatest slope u the shoulder can have without causing the car to slip or tip over if the car travels along the shoulder at constant velocity. G 0.75m B 1.5m Tipping: A θ a+ M A = 0; -W cos u W sin u = 0 tan u = 1 u = m Slipping: 0.75m Q+ F x = 0; a+ F y = 0; 0.4 N - W sin u = 0 N - W cos u = 0 tan u = 0.4 u = 21.8 (Car slips before it tips.)

16 8 16. If the coefficient of static friction between the collars A and B and the rod is m s = 0.6, determine the maximum angle u for the system to remain in equilibrium, regardless of the weight of cylinder D. Links AC and BC have negligible weight and are connected together at C by a pin. A 15 B 15 u u C D

17 8 17. If u = 15, determine the minimum coefficient of static friction between the collars A and B and the rod required for the system to remain in equilibrium, regardless of the weight of cylinder D. Links AC and BC have negligible weight and are connected together at C by a pin. A 15 B 15 u u C D

18 8 18. The 5-kg cylinder is suspended from two equal-length cords. The end of each cord is attached to a ring of negligible mass that passes along a horizontal shaft. If the rings can be separated by the greatest distance d = 400 mm and still support the cylinder, determine the coefficient of static friction between each ring and the shaft. d 600 mm 600 mm Equilibrium of the Cylinder: Referring to the FBD shown in Fig. a, + c F y = 0; 2BT 232 R - m(9.81) = 0 6 T = m Equilibrium of the Ring: Since the ring is required to be on the verge to slide, the frictional force can be computed using friction formula F f = mn as indicated in the FBD of the ring shown in Fig. b. Using the result of I, + c F y = 0; N m = 0 N = m : + F x = 0; m(4.905 m) m 2 6 = 0 m = 0.354

19 8 19. The 5-kg cylinder is suspended from two equal-length cords. The end of each cord is attached to a ring of negligible mass, which passes along a horizontal shaft. If the coefficient of static friction between each ring and the shaft is m s = 0.5, determine the greatest distance d by which the rings can be separated and still support the cylinder. d Friction: When the ring is on the verge to sliding along the rod, slipping will have to occur. Hence, F = mn = 0.5N. From the force diagram (T is the tension developed by the cord) Geometry: tan u = N 0.5N = 2 u = mm 600 mm d = cos = 537 mm

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21 8 21. The uniform pole has a weight W and length L. Its end B is tied to a supporting cord, and end A is placed against the wall, for which the coefficient of static friction is m s. Determine the largest angle u at which the pole can be placed without slipping. C L a + M B = 0; -N A (L cos u) - m s N A (L sin u) + W a L (1) 2 sin ub = 0 A : + F x = 0; N A - T sin u 2 = 0 (2) u L + c F y = 0; m s N A - W + T cos u 2 = 0 (3) B Substitute Eq. (2) into Eq. (3): m s T sin u 2 - W + T cos u 2 = 0 W = Tacos u 2 + m s sin u 2 b (4) Substitute Eqs. (2) and (3) into Eq. (1): T sin u 2 cos u - T cos u 2 sin u + W 2 sin u = 0 (5) Substitute Eq. (4) into Eq. (5): sin u 2 cos u - cos u 2 sin u cos u 2 sin u m s sin u 2 sin u = 0 -sin u acos u 2 + m s sin u 2 bsin u = 0 cos u 2 + m s sin u 2 = 1 cos u 2 cos 2 u 2 + m s sin u 2 cos u 2 = 1 m s sin u 2 cos u 2 = sin2 u 2 tan u 2 = m s u = 2 tan - 1 m s Also, because we have a three force member, L 2 = L 2 cos u + tan fa L sin ub 2 1 = cos u + m s sin u m s = 1 - cos u sin u = tan u 2 u = 2 tan -1 m s

22 8 22. If the clamping force is F = 200 N and each board has a mass of 2 kg, determine the maximum number of boards the clamp can support. The coefficient of static friction between the boards is m s = 0.3, and the coefficient of static friction between the boards and the clamp is m s =0.45. F F Free-Body Diagram: The boards could be on the verge of slipping between the two boards at the ends or between the clamp. Let n be the number of boards between the clamp. Thus, the number of boards between the two boards at the ends is n - 2. If the boards slip between the two end boards, then F = m s N = 0.3(200) = 60 N. Equations of Equilibrium: Referring to the free-body diagram shown in Fig. a, we have + c F y = 0; 2(60) - (n - 2)(2)(9.81) = 0 n = 8.12 If the end boards slip at the clamp, then F =m s N = 0.45(200) = 90 N. By referring to the free-body diagram shown in Fig. b, we have a+ c F y = 0; 2(90) - n(2)(9.81) = 0 n = 9.17 Thus, the maximum number of boards that can be supported by the clamp will be the smallest value of n obtained above, which gives a+ M clamp = 0; n = (2)(9.81)(n - 1)2 = (n - 1) = 0 n = 7.12 n = 7

23 8 23. A 35-kg disk rests on an inclined surface for which m s = 0.3. Determine the maximum vertical force P that may be applied to link AB without causing the disk to slip at C. P 200 mm 300 mm 600 mm 200 mm A B Equations of Equilibrium: From FBD (a), C 30 a+ M B = 0; P A y = 0 A y = P From FBD (b), + c F y = 0 N C sin 60 - F C sin P = 0 (1) a + M O = 0; F C P12002 = 0 (2) Friction: If the disk is on the verge of moving, slipping would have to occur at point C. Hence, F C = m s N C = 0.3N C. Substituting this value into Eqs. (1) and (2) and solving, we have P = N N C = N

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25 8 25. The block brake is used to stop the wheel from rotating when the wheel is subjected to a couple moment M 0 If the coefficient of static friction between the wheel and the block is s, determine the smallest force P that should be applied. Solution: M C = 0; PaNb s Nc 0 N Pa b s c M O = 0; s Nr M O 0 s Par b s c M O P M O b s c s ra

26 8 26. The block brake is used to stop the wheel from rotating when the wheel is subjected to a couple moment M 0 If the coefficient of static friction between the wheel and the block is s, show that the brake is self locking, i. e., P 0, provided b c s Solution: M C = 0; PaNb s Nc 0 N Pa b s c M O = 0; s Nr M O 0 s Par b s c M O P M O b s c s ra P < 0 if b s c 0 i.e. if b c s

27 8 27. The block brake is used to stop the wheel from rotating when the wheel is subjected to a couple moment M 0 If the coefficient of static friction between the wheel and the block is s, determine the smallest force P that should be applied if the couple moment M O is applied counterclockwise. Solution: M C = 0; PaNb s Nc 0 N Pa b s c M O = 0; s NrM O 0 s Par b s c M O P M O b s c s ra

28 8-28. The 10-kg.

29 8 29. The friction pawl is pinned at A and rests against the wheel at B. It allows freedom of movement when the wheel is rotating counterclockwise about C. Clockwise rotation is prevented due to friction of the pawl which tends to bind the wheel. If 1m s 2 B = 0.6, determine the design angle u which will prevent clockwise motion for any value of applied moment M. Hint: Neglect the weight of the pawl so that it becomes a two-force member. Friction: When the wheel is on the verge of rotating, slipping would have to occur. Hence, F B = mn B = 0.6N B. From the force diagram ( F AB is the force developed in the two force member AB) M A θ B 20 C tan120 + u2 = 0.6N B N B = 0.6 u = 11.0

30 8 30. If u = 30 determine the minimum coefficient of static friction at A and B so that equilibrium of the supporting frame is maintained regardless of the mass of the cylinder C. Neglect the mass of the rods. u C u L L Free-Body Diagram: Due to the symmetrical loading and system, ends A and B of the rod will slip simultaneously. Since end B tends to move to the right, the friction force F B must act to the left as indicated on the free-body diagram shown in Fig. a. A B Equations of Equilibrium: We have : + F x = 0; F BC sin 30 - F B = 0 + c F y = 0; N B - F BC cos 30 = 0 F B = 0.5F BC N B = F BC Therefore, to prevent slipping the coefficient of static friction ends A and B must be at least m s = F B N B = 0.5F BC F BC = 0.577

31 8 31. If the coefficient of static friction at A and B is m s = 0.6, determine the maximum angle u so that the frame remains in equilibrium, regardless of the mass of the cylinder. Neglect the mass of the rods. u C u L L Free-Body Diagram: Due to the symmetrical loading and system, ends A and B of the rod will slip simultaneously. Since end B is on the verge of sliding to the right, the friction force F B must act to the left such that F B = m s N B = 0.6N B as indicated on the free-body diagram shown in Fig. a. A B Equations of Equilibrium: We have + c F y = 0; N B - F BC cos u = 0 N B = F BC cos u : + F x = 0; F BC sin u - 0.6(F BC cos u) = 0 tan u = 0.6 u = 31.0

32 8 32. The semicylinder of mass m and radius r lies on the rough inclined plane for which f = 10 and the coefficient of static friction is m s = 0.3. Determine if the semicylinder slides down the plane, and if not, find the angle of tip u of its base AB. A θ r B Equations of Equilibrium: φ a + M F1r2-9.81m sin ua 4r O = 0; (1) 3p b = 0 : + F x = 0; F cos 10 - N sin 10 = 0 (2) + c F y = 0 F sin 10 + N cos m = 0 (3) Solving Eqs. (1), (2) and (3) yields N = 9.661m F = 1.703m u = 24.2 Friction: The maximum friction force that can be developed between the semicylinder and the inclined plane is F max = mn = m = 2.898m. Since F max 7 F = 1.703m, the semicylinder will not slide down the plane.

33 8 33. The semicylinder of mass m and radius r lies on the rough inclined plane. If the inclination f = 15, determine the smallest coefficient of static friction which will prevent the semicylinder from slipping. B A θ r Equations of Equilibrium: φ +Q F x = 0; a+ F y = 0; F m sin 15 = 0 F = 2.539m N m cos 15 = 0 N = 9.476m Friction: If the semicylinder is on the verge of moving, slipping would have to occur. Hence, F = m s N 2.539m = m s m2 m s = 0.268

34 8 34. The coefficient of static friction between the 150-kg crate and the ground is m s = 0.3, while the coefficient of static friction between the 80-kg man s shoes and the ground is œ m s = 0.4. Determine if the man can move the crate. Free - Body Diagram: Since P tends to move the crate to the right, the frictional force F C will act to the left as indicated on the free - body diagram shown in Fig. a. Since the crate is required to be on the verge of sliding the magnitude of F C can be computed using the friction formula, i.e. F C = m s N C = 0.3 N C. As indicated on the free - body diagram of the man shown in Fig. b, the frictional force F m acts to the right since force P has the tendency to cause the man to slip to the left. 30 Equations of Equilibrium: Referring to Fig. a, + c F y = 0; N C + P sin (9.81) = 0 : + F x = 0; P cos N C = 0 Solving, P = N N C = N Using the result of P and referring to Fig. b, we have + c F y = 0; N m sin 30-80(9.81) = 0 N m = N : + F x = 0; F m cos 30 = 0 F m = N Since F m 6 F max = m s N m = 0.4( ) = N, the man does not slip. Thus, he can move the crate.

35 8 35. If the coefficient of static friction between the crate and the ground is m s = 0.3, determine the minimum coefficient of static friction between the man s shoes and the ground so that the man can move the crate. Free - Body Diagram: Since force P tends to move the crate to the right, the frictional force F C will act to the left as indicated on the free - body diagram shown in Fig. a. Since the crate is required to be on the verge of sliding, F C = m s N C = 0.3 N C. As indicated on the free - body diagram of the man shown in Fig. b, the frictional force F m acts to the right since force P has the tendency to cause the man to slip to the left. 30 Equations of Equilibrium: Referring to Fig. a, + c F y = 0; N C + P sin (9.81) = 0 : + F x = 0; P cos N C = 0 Solving yields P = N N C = N Using the result of P and referring to Fig. b, + c F y = 0; N m sin 30-80(9.81) = 0 N m = N : + F x = 0; F m cos 30 = 0 F m = N Thus, the required minimum coefficient of static friction between the man s shoes and the ground is given by m s = F m N m = = 0.376

36 8 36. The thin rod has a weight W and rests against the floor and wall for which the coefficients of static friction are m A and m B, respectively. Determine the smallest value of u for which the rod will not move. L B Equations of Equilibrium: A u : + F x = 0; F A - N B = 0 + c F y = 0 N A + F B - W = 0 (1) (2) a + M A = 0; N B (L sin u) + F B (cos u)l - W cos ua L (3) 2 b = 0 Friction: If the rod is on the verge of moving, slipping will have to occur at points A and B. Hence, F A = m A N A and F B = m B N B. Substituting these values into Eqs. (1), (2), and (3) and solving we have N A = W 1 + m A m B N B = m A W 1 + m A m B u = tan - 1 a 1 - m Am B b 2m A

37 8 37. Determine the magnitude of force P needed to start towing the crate of mass M. Also determine the location of the resultant normal force acting on the crate, measured from point A. Given: M 40 kg c 200 mm s 0.3 d 3 a 400 mm e 4 b 800 mm Solution: Initial guesses: N C 200 N P 50 N Given F x = 0; d d 2 e 2 P s N C 0 F y = 0; N C Mg ep 0 d 2 e 2 N C P Find N C P N C N P 140 N M O = 0; s a N C 2 ep b N 1 x d 2 e x 1 s N C a d 2 e 2 epb x mm 2 N C d 2 e 2 b Thus, the distance from A is A x A mm 2

38 8 38. Determine the friction force on the crate of mass M, and the resultant normal force and its position x, measured from point A, if the force is P. Given: M 40 kg s 0.5 a b c 400 mm k mm d mm e 4 P 300 N Solution: Initial guesses: F C 25 N N C 100 N Given F x = 0; P d d 2 e 2 F C 0 F y = 0; N C Mg e P d 2 e 2 0 F C N C Find F C N C F Cmax s N C Since F C N > F Cmax N then the crate slips F C k N C F C N C N M O = 0; N C x P e d 2 e 2 d a P c 0 d 2 e 2 x P e a dc N C d 2 e 2 b Since x 0.39 m < 0.40 m 2 Then the block does not tip. x 1 a x x m

39 8 39. Determine the smallest force the man must exert on the rope in order to move the 80-kg crate. Also, what is the angle u at this moment? The coefficient of static friction between the crate and the floor is m s = u Crate: : + F x = 0; 0.3N C - T sin u = 0 + c F y = 0; N C + T cos u - 80(9.81) = 0 (1) (2) Pulley: : + F x = 0; -T cos 30 + T cos 45 + T sin u = 0 + c F y = 0; T sin 30 + T sin 45 - T cos u = 0 Thus, T = T sin u T = T cos u u = tan - 1 a b = 7.50 T = T (3) From Eqs. (1) and (2), N C = 239 N T =550 N So that T = 452 N

40 8 40. The spool of wire having a mass M rests on the ground at A and against the wall at B. Determine the force P required to begin pulling the wire horizontally off the spool. The coefficient of static friction between the spool and its points of contact is s. Units Used: kn Given: M 10 3 N 150 kg s 0.25 a b 0.45 m 0.25 m Solution: Initial guesses: P 100 N F A 10 N N A 20 N N B 30 N F B 10 N Given F y = 0; N A F B F x = 0; F A N B Mg0 P 0 M B = 0; P b M g a N A a F A a 0 F A s N A F B s N B P F A F B N A N B Find P F A F B N A N B F A N A F B N B kn P 1.14 kn

41 8 41. The spool of wire having a mass M rests on the ground at A and against the wall at B. Determine the forces acting on the spool at A and B for the given force P. The coefficient of static friction between the spool and the ground at point A is s. The wall at B is smooth. Units Used: kn Given: 10 3 N P M 800 N a 0.45 m 150 kg b 0.25 m s 0.35 Solution: Assume no slipping Initial guesses : F A 10N N A 10N N B 10N F Amax 10N Given F x = 0; F A N B P 0 F y = 0; N A Mg 0 M 0 = 0; P b F A a 0 F Amax s N A F A F Amax N A N B Find F A F Amax N A N B F A F Amax N If F A 444 N < F Amax 515 N then our no-slip assumption is good. N A F A kn N B 1.24 kn

42 8 42. The friction hook is made from a fixed frame which is shown colored and a cylinder of negligible weight. A piece of paper is placed between the smooth wall and the cylinder. If u = 20, determine the smallest coefficient of static friction m at all points of contact so that any weight W of paper p can be held. Paper: + c F y = 0; F = 0.5W u p W F = mn; F = mn N = 0.5W m Cylinder: a+ M O = 0; F = 0.5W : + F x = 0; N cos 20 + F sin W m = 0 + c F y = 0; N sin 20 - F cos W = 0 F = mn; m 2 sin m cos 20 - sin 20 = 0 m = 0.176

43 8 43. The uniform rod has a mass of 10 kg and rests on the inside of the smooth ring at B and on the ground at A. If the rod is on the verge of slipping, determine the coefficient of static friction between the rod and the ground. B C 0.5 m a+ m A = 0; N B (0.4) (0.25 cos 30 ) = m N B = N 30 + c F y = 0; N A cos 30 = 0 N A = N A : + F x = 0; m(52.12) sin 30 = 0 m = 0.509

44 8 44. The rings A and C each weigh W and rest on the rod, which has a coefficient of static friction of m s. If the suspended ring at B has a weight of 2W, determine the largest distance d between A and C so that no motion occurs. Neglect the weight of the wire. The wire is smooth and has a total length of l. A d C B Free-Body Diagram: The tension developed in the wire can be obtained by considering the equilibrium of the free-body diagram shown in Fig. a. + c F y = 0; 2T sin u - 2w = 0 T = w sin u Due to the symmetrical loading and system, rings A and C will slip simultaneously. Thus, it s sufficient to consider the equilibrium of either ring. Here, the equilibrium of ring C will be considered. Since ring C is required to be on the verge of sliding to the left, the friction force F C must act to the right such that F C = m s N C as indicated on the free-body diagram of the ring shown in Fig. b. Equations of Equilibrium: Using the result of T and referring to Fig. b, we have + c F y = 0; : + F x = 0; W N C - w - c sin u d sin u = 0 W m s (2w) - c sin u d cos u = 0 tan u = 1 2m s N C = 2w From the geometry of Fig. c, we find that Thus, tan u = A a l 2 b 2 - a d 2 b 2 d 2 = 2l2 - d 2. d 2l 2 - d 2 = 1 d 2m s 2m s l d = m s

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46 8 46. The beam AB has a negligible mass and thickness and is subjected to a triangular distributed loading. It is supported at one end by a pin and at the other end by a post having a mass of 50 kg and negligible thickness. Determine the minimum force P needed to move the post.the coefficients of static friction at B and C are m B = 0.4 and m C = 0.2, respectively. A 2m 400 mm 300 mm 800 N/m B P C Member AB: a+ M A = 0; -800a 4 3 b + N B (2) = 0 N B = N Post: Assume slipping occurs at C; F C = 0.2 N C a+ M C = 0; P(0.3) + F B(0.7) = 0 : + F x = 0; + c F y = 0; 4 5 P - F B - 0.2N C = P + N C (9.81) = 0 P = 355 N N C = N F B = N (F B ) max = 0.4(533.3) = N N (O.K.!)

47 8 47. The beam AB has a negligible mass and thickness and is subjected to a triangular distributed loading. It is supported at one end by a pin and at the other end by a post having a mass of 50 kg and negligible thickness. Determine the two coefficients of static friction at B and at C so that when the magnitude of the applied force is increased to P = 150 N, the post slips at both B and C simultaneously. A 2m 400 mm 300 mm 800 N/m B P C Member AB: a+ M A = 0; -800a 4 3 b + N B (2) = 0 N B = N Post: + c F y = 0; N C a 3 5 b - 50(9.81) = 0 N C = N a+ M C = 0; (150)(0.3) + F B(0.7) = 0 F B = N : + F x = 0; 4 5 (150) - F C = 0 F C = N m C = F C N C = = m B = F B N B = =

48 8 48. The beam AB has a negligible mass and thickness and is subjected to a force of 200 N. It is supported at one end by a pin and at the other end by a spool having a mass of 40 kg. If a cable is wrapped around the inner core of the spool, determine the minimum cable force P needed to move the spool. The coefficients of static friction at B and D are m B = 0.4 and m D = 0.2, respectively. A 200 N 2m 1m 1m B 0.1 m 0.3 m D P Equations of Equilibrium: From FBD (a), a+ M A = 0; From FBD (b), N B = 0 N B = N + c F y = 0 N D = 0 N D = N : + F x = 0; P - F B - F D = 0 (1) a + M D = 0; F B P10.22 = 0 (2) Friction: Assuming the spool slips at point B, then F B = ms B N B = = N. Substituting this value into Eqs. (1) and (2) and solving, we have F D = N P = N = 107 N Since F D max = m sd N D = = N 7 F D, the spool does not slip at point D. Therefore the above assumption is correct.

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51 8 51. The block of weight W is being pulled up the inclined plane of slope a using a force P. If P acts at the angle f as shown, show that for slipping to occur, P = W sin1a + u2>cos1f - u2, where u is the angle of friction; u = tan -1 m. P f a Q + F x = 0; P cos f - W sin a - mn = 0 + a F y = 0; N - W cos a + P sin f = 0 Let m = tan u P cos f - W sin a - m(w cos a - P sin f) = 0 sin a + m cos a P = W a cos f + m sin f b sin (a + u) P = W a cos (f - u) b (QED)

52 8 52. Determine the angle f at which P should act on the block so that the magnitude of P is as small as possible to begin pushing the block up the incline. What is the corresponding value of P? The block weighs W and the slope a is known. P f a Slipping occurs u = tan - 1 u. when sin (a + u) P = W a cos (f - u) b where u is the angle of friction dp df sin (a + u) sin (f - u) = W a cos 2 b = 0 (f - u) sin (a + u) sin (f - u) = 0 sin (a + u) = 0 or sin (f - u) = 0 a = -u P = W sin (a + f) f = u

53 ..

54 8 54. The uniform beam has a weight W and length 4a. It rests on the fixed rails at A and B. If the coefficient of static friction at the rails is m s, determine the horizontal force P, applied perpendicular to the face of the beam, which will cause the beam to move. a 3a B From FBD (a), A P + c F = 0; a+ M B = 0; N A + N B - W = 0 -N A 13a2 + W12a2 = 0 N A = 2 3 W N B = 1 3 W Support A can sustain twice as much static frictional force as support B. From FBD (b), + c F = 0; a+ M B = 0; P + F B - F A = 0 -P14a2 + F A 13a2 = 0 F A = 4 3 P F B = 1 3 P The frictional load at A is 4 times as great as at B. The beam will slip at A first. P = 3 4 F A max = 3 4 m s N A = 1 2 m s W

55 8 55. Determine the greatest angle u so that the ladder does not slip when it supports the 75-kg man in the position shown. The surface is rather slippery, where the coefficient of static friction at A and B is m s = m G C u Free-Body Diagram: The slipping could occur at either end A or B of the ladder.we will assume that slipping occurs at end B. Thus, F B = m s N B = 0.3N B. 2.5 m 2.5 m Equations of Equilibrium: Referring to the free-body diagram shown in Fig. b, we have : + F x = 0; F BC sin u>2-0.3n B = 0 F BC sin u>2 = 0.3N B (1) A B + c F y = 0; N B - F BC cos u>2 = 0 F BC cos u>2 = N B (2) Dividing Eq. (1) by Eq. (2) yields tan u>2 = 0.3 u = = 33.4 Using this result and referring to the free-body diagram of member AC shown in Fig. a, we have a+ M A = 0; F BC sin (2.5) - 75(9.81)(0.25) = 0 F BC = N : + F x = 0; F A sin = 0 2 F A = N + c F y = 0; N A cos (9.81) = 0 2 N A = N Since F A 6 (F A ) max = m s N A = 0.3(607.73) = N, end A will not slip. Thus, the above assumption is correct.

56 8 56. The uniform 6-kg slender rod rests on the top center of the 3-kg block. If the coefficients of static friction at the points of contact are m A = 0.4, m B = 0.6, and m C = 0.3, determine the largest couple moment M which can be applied to the rod without causing motion of the rod. C 800 mm M Equations of Equilibrium: From FBD (a), : + F x = 0; F B - N C = 0 (1) 300 mm A B 600 mm + c F y = 0; a+ M B = 0; N B + F C = 0 F C N C M = 0 (2) (3) 100 mm 100 mm From FBD (b), + c F y = 0; N A - N B = 0 (4) : + F x = 0; F A - F B = 0 (5) a+ M O = 0; F B N B 1x x2 = 0 (6) Friction: Assume slipping occurs at point C and the block tips, then F C = ms C N C = 0.3NC and x = 0.1 m. Substituting these values into Eqs. (1), (2), (3), (4), (5), and (6) and solving, we have M = N # m = 8.56 N # m N B = N N A = N F A = F B = N C = N Since 1F A 2 max = m sa N A = = N 7 F A, the block does not slip. Also, 1F B 2 max = m sb N B = = N 7 F B, then slipping does not occur at point B. Therefore, the above assumption is correct.

57 8 57. The disk has a weight W and lies on a plane which has a coefficient of static friction m. Determine the maximum height h to which the plane can be lifted without causing the disk to slip. z h a y 2a x Unit Vector: The unit vector perpendicular to the inclined plane can be determined using cross product. Then Thus A = (0-0)i + (0 - a)j + (h - 0)k = -aj + hk B = (2a - 0)i + (0 - a)j + (0-0)k = 2ai - aj i j k N = A * B = 3 0 -a h3 = ahi + 2ahj + 2a 2 k 2a -a 0 n = N N = ahi + 2ahj + 2a2 k a25h 2 + 4a 2 cos g = 2a hence sin g = 25h 2 + 4a 2 25h 25h 2 + 4a 2 Equations of Equilibrium and Friction: When the disk is on the verge of sliding down the plane, F = mn. F n = 0; N - W cos g = 0 N = W cos g F t = 0; W sin g - mn = 0 N = W sin g m (1) (2) Divide Eq. (2) by (1) yields sin g m cos g = 1 ma 15h h + 4a 2a b 5h + 4a = 1 h = 2 25 am

58 8 58. Determine the largest angle u that will cause the wedge to be self-locking regardless of the magnitude of horizontal force P applied to the blocks. The coefficient of static friction between the wedge and the blocks is m s = 0.3. Neglect the weight of the wedge. P u P Free-Body Diagram: For the wedge to be self-locking, the frictional force F indicated on the free-body diagram of the wedge shown in Fig. a must act downward and its magnitude must be F m s N = 0.3N. Equations of Equilibrium: Referring to Fig. a, we have + c F y = 0; 2N sin u>2-2f cos u>2 = 0 F = N tan u>2 Using the requirement F 0.3N, we obtain N tan u>2 0.3N u = 33.4

59 8 59. If the beam AD is loaded as shown, determine the horizontal force P which must be applied to the wedge in order to remove it from under the beam. The coefficients of static friction at the wedge s top and bottom surfaces are m CA = 0.25 and m CB = 0.35, respectively. If P = 0, is the wedge self-locking? Neglect the weight and size of the wedge and the thickness of the beam. D 3m 4 kn/m 4m A C B 10 P Equations of Equilibrium and Friction: If the wedge is on the verge of moving to the right, then slipping will have to occur at both contact surfaces. Thus, F A = m sa N A = 0.25N A a nd F B = m sb N B = 0.35N B. From FBD (a), a+ M D = 0; N A cos N A sin N A = kn = 0 From FBD (b), + c F y = 0; N B sin sin 10 = 0 N B = kn : + F x = 0; P cos cos = 0 P = 5.53 kn Since a force P 7 0 when P = 0. is required to pull out the wedge, the wedge will be self-locking

60 8 60. The wedge has a negligible weight and a coefficient of static friction m s = 0.35 with all contacting surfaces. Determine the largest angle u so that it is self-locking. This requires no slipping for any magnitude of the force P applied to the joint. P u u 2 2 P Friction: When the wedge is on the verge of slipping, then F = mn = 0.35N. From the force diagram (P is the locking force.), tan u 2 = 0.35N N = 0.35 u = 38.6

61 8 61. If the spring is compressed 60 mm and the coefficient of static friction between the tapered stub S and the slider A is m SA = 0.5, determine the horizontal force P needed to move the slider forward. The stub is free to move without friction within the fixed collar C. The coefficient of static friction between A and surface B is m AB = 0.4. Neglect the weights of the slider and stub. k 300 N/m C Stub: S + c F y = 0; N A cos N A sin (0.06) = 0 N A = N P A 30 Slider: B + c F y = 0; N B cos (29.22) sin 30 = 0 N B = 18 N : + F x = 0; P - 0.4(18) sin (29.22) cos 30 = 0 P = 34.5 N

62 8 62. If P = 250 N, determine the required minimum compression in the spring so that the wedge will not move to the right. Neglect the weight of A and B. The coefficient of static friction for all contacting surfaces is m s = Neglect friction at the rollers. k 15 kn/m B Free-Body Diagram: The spring force acting on the cylinder is F sp = kx = 15(10 3 )x. Since it is required that the wedge is on the verge to slide to the right, the frictional force must act to the left on the top and bottom surfaces of the wedge and their magnitude can be determined using friction formula. P A 10 (F f ) 1 = mn 1 = 0.35N 1 (F f ) 2 = 0.35N 2 Equations of Equilibrium: Referring to the FBD of the cylinder, Fig. a, + c F y = 0; N 1-15(10 3 )x = 0 N 1 = 15(10 3 )x Thus, (F f ) 1 = (10 3 )x4 = 5.25(10 3 )x Referring to the FBD of the wedge shown in Fig. b, + c F y = 0; N 2 cos N 2 sin 10-15(10 3 )x = 0 N 2 = (10 3 )x : + F x = 0; (10 3 )x (10 3 )x4cos (10 3 )x4sin 10 = 0 x = m = 18.3 mm

63 8 63. Determine the minimum applied force P required to move wedge A to the right.the spring is compressed a distance of 175 mm. Neglect the weight of A and B. The coefficient of static friction for all contacting surfaces is m s = Neglect friction at the rollers. k =15kN/m B Equations of Equilibrium and Friction: Using the spring formula, F sp = kx = = kn. If the wedge is on the verge of moving to the right, then slipping will have to occur at both contact surfaces. Thus, F A = msn A = 0.35N A and F B = msn B = 0.35N B. From FBD (a), P A 10 + c F y = 0; From FBD (b), N B = 0 N B = kn + c F y = 0; N A cos N A sin = 0 N A = kn : + F x = 0; P cos sin 10 = 0 P = 2.39 kn

64 8 64..

65 8 65. The coefficient of static friction between wedges B and C is m s = 0.6 and between the surfaces of contact B and A and C and D, m s =0.4. If the spring is compressed 200 mm when in the position shown, determine the smallest force P needed to move wedge C to the left. Neglect the weight of the wedges. 15 A B k D N/m C P Wedge B: : + F x = 0; N AB - 0.6N BC cos 15 - N BC sin 15 = 0 + c F y = 0; N BC cos N BC sin N AB = 0 N BC = N N AB = N Wedge C: + c F y = 0; N CD cos N CD sin (210.4) sin cos 15 = 0 N CD = N : + F x = 0; sin (197.8) cos sin (210.4) cos 15 - P = 0 P = 304 N

66 8 66. The coefficient of static friction between the wedges B and C is m s = 0.6 and between the surfaces of contact B and A and C and D, m s =0.4. If P = 50 N, determine the largest allowable compressionof the spring without causingwedgec to move to the left. Neglect the weight of the wedges. 15 A B k D N/m C P Wedge C: : + F x = 0; (N CD + N BC ) sin 15 + (0.4N CD + 0.6N BC ) cos = 0 c + F y = 0; (N CD - N BC ) cos 15 + (-0.4N CD + 0.6N BC ) sin 15 = 0 N BC = N N CD = N Wedge B: : + F x = 0; N AB - 0.6(34.61) cos sin 15 = 0 N AB = N c + F y = 0; cos (34.61) sin (29.01) - 500x = 0 x = m = 32.9 mm

67 8 67. The vise is used to grip the pipe. If a horizontal force F 1 is applied perpendicular to the end of the handle of length l, determine the compressive force F developed in the pipe. The square threads have a mean diameter d and a lead a. How much force must be applied perpendicular to the handle to loosen the vise? Given: F 1 100N d 37.5mm s 0.3 L 250mm a 5mm Solution: d r 2 a atan 2.43 deg 2r atan s deg F 1 L = Fr tan( ) L F F 1 F 3.84 kn rtan( ) To loosen screw, PL = Fr tan( ) tan P Fr ( ) P 73.3 N L

68 8 68. Determine the couple forces F that must be applied to the handle of the machinist s vise in order to create a compressive force F A in the block. Neglect friction at the bearing A. The guide at B is smooth so that the axial force on the screw is F A. The single square-threaded screw has a mean radius b and a lead c, and the coefficient of static friction is s. Given: a 125mm F A 400N b 6mm c 8mm s 0.27 Solution: atan s deg c atan deg 2b F2a = F A btan( ) b F F A tan( ) F 4.91 N 2a

69 8 69. The column is used to support the upper floor. If a force F = 80 N is applied perpendicular to the handle to tighten the screw, determine the compressive force in the column. The square-threaded screw on the jack has a coefficient of static friction of m s = 0.4, mean diameter of 25 mm, and a lead of 3 mm. F 0.5 m M = W1r2 tan1f s + u p 2 f s = tan = u p = tan -1 3 c 2p d = = W tan W = 7.19 kn

70 8 70. If the force F is removed from the handle of the jack in Prob. 8-69, determine if the screw is self-locking. f s = tan = F 0.5 m u p = tan -1 3 c 2p d = Since f s 7 u p, the screw is self locking.

71 8 71. If the clamping force at G is 900 N, determine the horizontal force F that must be applied perpendicular to the handle of the lever at E. The mean diameter and lead of both single square-threaded screws at C and D are 25 mm and 5 mm, respectively. The coefficient of static friction is m s = 0.3. G 200 mm A 200 mm C Referring to the free-body diagram of member GAC shown in Fig. a, we have M A = 0; F CD (0.2) - 900(0.2) = 0 F CD = 900 N Since the screw is being tightened, Eq. 8 3 should be used. Here, u = tan -1 a L 2pr b = tan c ; 2p(12.5) d = B D 125 mm E f s = tan - 1 m s = tan - 1 (0.3) = ; and M = F(0.125). Since M must overcome the friction of two screws, M = 2[Wr tan(f s + u)] F(0.125) = 2 [900(0.0125)tan( )] F = 66.7 N Note: Since f s 7 u, the screw is self-locking.

72 8 72. If a horizontal force of F = 50 N is applied perpendicular to the handle of the lever at E, determine the clamping force developed at G. The mean diameter and lead of the single square-threaded screw at C and D are 25 mm and 5 mm, respectively. The coefficient of static friction is m s = 0.3. G 200 mm A 200 mm C B D E Since the screw is being tightened, Eq. 8 3 should be used. Here, tan -1 5 c ; 2p(12.5) d = u = tan -1 a L 2pr b = 125 mm f s = tan -1 m s = tan -1 (0.3) = ; and M = 50(0.125). Since M must overcome the friction of two screws, M = 2[Wr tan(f s + u)] 50(0.125) = 2[F CD (0.0125)tan( )] F CD = N Using the result of F CD and referring to the free-body diagram of member GAC shown in Fig. a, we have M A = 0; (0.2) - F G (0.2) = 0 F G = 674 N Note: Since f s 7 u, the screws are self-locking.

73 8 73. A turnbuckle, similar to that shown in Fig. 8 17, is used to tension member AB of the truss. The coefficient of the static friction between the square threaded screws and the turnbuckle is m s = 0.5. The screws have a mean radius of 6 mm and a lead of 3 mm. If a torque of M = 10 N # m is applied to the turnbuckle, to draw the screws closer together, determine the force in each member of the truss. No external forces act on the truss. B M D 4m Frictional Forces on Screw: Here, u = tan -1 a l 2pr b = 3 tan-1 c 2p162 d = 4.550, M = 10 N # m and f s = tan -1 m s = tan = Since friction at two screws must be overcome, then, W = 2F AB. Applying Eq. 8 3, we have C 3m A M = Wr tan 1u + f S 2 10 = 2F AB tan F AB = N 1T2 = 1.38 kn 1T2 Note: Since f s 7 u, the screw is self-locking. It will not unscrew even if moment M is removed. Method of Joints: Joint B: : + F x = 0; a 3 5 b - F BD = 0 F BD = N1C2 = 828 N 1C2 + c F y = 0; F BC a 4 5 b = 0 F BC = N 1C2 = 1.10 kn 1C2 Joint A: :+ F x = 0; F AC a 3 5 b = 0 F AC = N 1C2 = 828 N 1C2 + c F y = 0; a 4 5 b - F AD = 0 F AD = N 1C2 = 1.10 kn 1C2 Joint C: :+ F x = 0; F CD a 3 5 b = 0 F CD = N 1T2 = 1.38 kn 1T2 + c F y = 0; C y a 4 5 b = 0 C y = 0 (No external applied load. check!)

74 8 74. A turnbuckle, similar to that shown in Fig. 8 17, is used to tension member AB of the truss. The coefficient of the static friction between the square-threaded screws and the turnbuckle is m s = 0.5. The screws have a mean radius of 6 mm and a lead of 3 mm. Determine the torque M which must be applied to the turnbuckle to draw the screws closer together, so that the compressive force of 500 N is developed in member BC. B M D 4m Method of Joints: Joint B: C 3m A + c F y = 0; F AB a 4 5 b = 0 F AB = 625 N 1C2 Frictional Forces on Screws: Here, u = tan -1 a l 2pr b = 3 tan-1 c 2p162 d = and f s = tan -1 m s = tan = Since friction at two screws must be overcome, then, W = 2F AB = = 1250 N. Applying Eq. 8 3, we have M = Wr tan1u + f2 = tan = 4.53 N # m Note: Since f s 7 u, the screw is self-locking. It will not unscrew even if moment M is removed.

75 8 75. The shaft has a square-threaded screw with a lead of 8 mm and a mean radius of 15 mm. If it is in contact with a plate gear having a mean radius of 30 mm, determine the resisting torque M on the plate gear which can be overcome if a torque of 7N# m is applied to the shaft. The coefficient of static friction at the screw is m B = 0.2. Neglect friction of the bearings located at A and B. B 15 mm M Frictional Forces on Screw: Here, u = tan -1 a l 2pr b = 8 tan-1 c 2p1152 d = 4.852, W = F, M = 7N# m and f s = tan -1 m s = tan = Applying Eq. 8 3, we have A 30 mm M = Wr tan 1u + f2 7 = F tan N m F = N Note: Since f s 7 u, the screw is self-locking. It will not unscrew even if force F is removed. Equations of Equilibrium: a+ M O = 0; M = 0 M = 48.3 N # m

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77 8 77. The fixture clamp consist of a square-threaded screw having a coefficient of static friction of m s = 0.3, mean diameter of 3 mm, and a lead of 1 mm. The five points indicated are pin connections. Determine the clamping force at the smooth blocks D and E when a torque of M = 0.08 N # m is applied to the handle of the screw. 30mm D 30 mm E 45 B C 40 mm A Frictional Forces on Screw: Here, u = tan - 1 l, 2pr = tan B 2p(1.5) R = W = P, M = 0.08 N # m and f s = tan - 1 m s = tan - 1 (0.3) = Applying Eq. 8 3, we have 40 mm 40 mm M =0.08N m M = Wr tan(u + f) 0.08 = P(0.0015) tan ( ) P = N Note: Since is removed. f S 7 u, the screw is self-locking. It will not unscrew even if moment M Equation of Equilibrium: a+ M C = 0; cos 45 (40) - F E cos 45 (40) - F E sin 45 (30) = 0 F E = N = 72.7 N The equilibrium of the clamped blocks requires that F D = F E = 72.7 N

78 8 78. The braking mechanism consists of two pinned arms and a square-threaded screw with left and righthand threads. Thus when turned, the screw draws the two arms together. If the lead of the screw is 4 mm, the mean diameter 12 mm, and the coefficient of static friction is m s = 0.35, determine the tension in the screw when a torque of 5N# m is applied to tighten the screw. If the coefficient of static friction between the brake pads A and B and the circular shaft is ms œ = 0.5, determine the maximum torque M the brake can resist. 200 mm A M B 5N m 300 mm 300 mm C D Frictional Forces on Screw: Here, u = tan -1 a l 2pr b = 4 tan-1 c 2p162 d = 6.057, M = 5N# m and f s = tan -1 m s = tan = Since friction at two screws must be overcome, then, W = 2P. Applying Eq. 8 3, we have M = Wr tan1u + f2 5 = 2P tan P = N = 880 N Note: Since f s 7 u, the screw is self-locking. It will not unscrew even if moment M is removed. Equations of Equilibrium and Friction: Since the shaft is on the verge to rotate about point O, then, F A = m s N A = 0.5N A and F B = m s N B = 0.5N B. From FBD (a), a+ M D = 0; N B = 0 N B = N From FBD (b), a + MO = 0; M = 0 M = 352 N # m

79 8 79. If a horizontal force of P = 100 N is applied perpendicular to the handle of the lever at A, determine the compressive force F exerted on the material. Each single squarethreaded screw has a mean diameter of 25 mm and a lead of 7.5 mm. The coefficient of static friction at all contacting surfaces of the wedges is m s = 0.2, and the coefficient of static friction at the screw is ms œ = B 15 C 15 A 250 mm Since the screws are being tightened, Eq. 8 3 should be used. Here, u = tan -1 a L 2pr b = tan c 2p(12.5) d = ; f s = tan - 1 m s = tan - 1 (0.15) = ; M = 100(0.25) = 25 N # m ; and W = T, where T is the tension in the screw shank. Since M must overcome the friction of two screws, M = 2[Wr, tan(f s + u)4 25 = 23T(0.0125) tan ( )4 T = N = 4.02 kn Referring to the free-body diagram of wedge B shown in Fig. a using the result of T, we have : + F x = 0; + c F y = 0; N -0.2N cos 15 - N sin 15 = 0 N +0.2N sin 15 - N cos 15 = 0 (1) (2) Solving, N = N N = N Using the result of N and referring to the free-body diagram of wedge C shown in Fig. b, we have + c F y = 0; 2( ) cos ( ) sin F = 0 F = N = 11.6 kn

80 8 80. Determine the horizontal force P that must be applied perpendicular to the handle of the lever at A in order to develop a compressive force of 12 kn on the material. Each single square-threaded screw has a mean diameter of 25 mm and a lead of 7.5 mm. The coefficient of static friction at all contacting surfaces of the wedges is m s = 0.2, and the coefficient of static friction at the screw is ms œ = B 15 C 15 A 250 mm Referring to the free-body diagram of wedge C shown in Fig. a, we have + c F y = 0; 2N cos N sin = 0 N = N Using the result of N and referring to the free-body diagram of wedge B shown in Fig. b, we have + c F y = 0; N cos ( ) sin 15 = 0 N =6000 N : + F x = 0; T sin ( ) cos (6000) = 0 T = N Since the screw is being tightened, Eq. 8 3 should be used. Here, u = tan - 1 L c 2pr d = 7.5 tan-1 c 2p(12.5) d = ; f s = tan -1 m s = tan -1 (0.15) = ; M = P(0.25); and W = T = N. Since M must overcome the friction of two screws, M = 23Wr tan (f s + u)4 P(0.25) = (0.0125) tan ( )4 P = 104 N

81 8 81. Determine the clamping force on the board A if the screw of the C clamp is tightened with a twist of M = 8N# m. The single square-threaded screw has a mean radius of 10 mm, a lead of 3 mm, and the coefficient of static friction is m s = M f s = tan - 1 (0.35) = u p = tan c 2p(10) d = A M = W(r) tan (f s + u p ) 8 = P(0.01) tan ( ) P = 1978 N = 1.98 kn

82 8 82. If the required clamping force at the board A is to be 50 N, determine the torque M that must be applied to the handle of the C clamp to tighten it down. The single square-threaded screw has a mean radius of 10 mm, a lead of 3 mm, and the coefficient of static friction is m s = M f s = tan - 1 (0.35) = u p = tan - 1 a l 2pr b = tan c 2p(10) d = A M = W(r) tan (f s + u p ) = 50(0.01) tan ( ) = N # m

83 8 83. A cylinder having a mass of 250 kg is to be supported by the cord which wraps over the pipe. Determine the smallest vertical force F needed to support the load if the cord passes (a) once over the pipe, b = 180, and (b) two times over the pipe, b = 540. Take m s = 0.2. Frictional Force on Flat Belt: Here, T 1 = F and T 2 = 250(9.81) = N. Applying Eq. 8 6, we have F a) If b = 180 = p rad T 2 = T 1 e mb = Fe 0.2p F = N = 1.31 kn b) If b = 540 = 3 p rad T 2 = T 1 e mb = Fe 0.2(3p) F = N = 372 N

84 8 84. A cylinder having a mass of 250 kg is to be supported by the cord which wraps over the pipe. Determine the largest vertical force F that can be applied to the cord without moving the cylinder.the cord passes (a) once over the pipe, b = 180, and (b) two times over the pipe, b = 540. Take m s = 0.2. F Frictional Force on Flat Belt: Here, T 1 = 250(9.81) = N and T 2 = F. Applying Eq. 8 6, we have a) If b = 180 = p rad T 2 = T 1 e mb F = e 0.2 p F = N = 4.60 kn b) If b = 540 = 3 p rad T 2 = T 1 e mb 0.2(3 p) F = e F = N = 16.2 kn

85 8 85. The cord supporting the cylinder of mass M passes around three pegs, A, B, C, where the coefficient of friction is s. Determine the range of values for the magnitude of the horizontal force P for which the cylinder will not move up or down. Given: M 6kg 45 deg s 0.2 g 9.81 m s 2 Solution: Total angle deg Forces P min Mge s P max Mge s Answer P min 15.9 N < P < P max N

86 8 86. A force of P = 25 N is just sufficient to prevent the 20-kg cylinder from descending. Determine the required force P to begin lifting the cylinder. The rope passes over a rough peg with two and half turns. The coefficient of static friction m s between the rope and the peg when the cylinder is on the verge of descending requires T 2 = 20(9.81) N, T 1 = P = 25 Nand b = 2.5(2p) = 5p rad. Thus, T 2 = T 1 e m sb 20(9.81) = 25e m s(5p) P In the case of the cylinder ascending T 2 = P and T 1 = 20(9.81) N. Using the result of, we can write m s In = 5pm s m s = T 2 = T 1 e m sb P = 20(9.81)e (5p) = N = 1.54 kn

87 8 87. The 20-kg cylinder A and 50-kg cylinder B are connected together using a rope that passes around a rough peg two and a half turns. If the cylinders are on the verge of moving, determine the coefficient of static friction between the rope and the peg. 75 mm In this case, T 1 = 50(9.81)N, T 2 = 20(9.81)N and b = 2.5(2 p) = 5p rad. Thus, T 1 = T 2 e m sb 50(9.81) = 20(9.81)e m s(5p) In 2.5 = m s (5p) m s = B A

88 8 88. The uniform bar AB is supported by a rope that passes over a frictionless pulley at C and a fixed peg at D. If the coefficient of static friction between the rope and the peg is D, determine the smallest distance x from the end of the bar at which a force F may be placed and not cause the bar to move. Given: F 20 N a 1m D 0.3 Solution: Initial guesses: T A 5N T B 10 N x 10 m Given M A = 0; F x T B a 0 F y = 0; T A T B F 0 D 2 T A T B e T A T B x Find T A T B x x 0.38 m

89 8 89. The truck, which has a mass of 3.4 Mg, is to be lowered down the slope by a rope that is wrapped around a tree. If the wheels are free to roll and the man at A can resist a pull of 300 N, determine the minimum number of turns the rope should be wrapped around the tree to lower the truck at a constant speed. The coefficient of kinetic friction between the tree and rope is m k = 0.3. A Q+ F x = 0; T sin 20 = 0 20 T 2 = T 2 = T 1 e mb = 300 e 0.3 b b = rad Approx. 2 turns (695 )

90 8 90. The smooth beam is being hoisted using a rope which is wrapped around the beam and passes through a ring at A as shown. If the end of the rope is subjected to a tension T and the coefficient of static friction between the rope and ring is m s = 0.3, determine the angle of u for equilibrium. T A θ Equation of Equilibrium: + c F x = 0; T - 2T cos u 2 = 0 T = 2T cos u 2 (1) Frictional Force on Flat Belt: Here, b = u T 2 = T and T 1 = T. Applying Eq , T 2 = T 1 e mb, we have T = T e 0.31u>22 = T e 0.15 u (2) Substituting Eq. (1) into (2) yields 2T cos u 2 = T e0.15 u e 0.15 u = 2 cos u 2 Solving by trial and error u = rad = 99.2 The other solution, which starts with T' = Te 0.3(0/2) based on cinching the ring tight, is rad = 139. Any angle from 99.2 to 139 is equilibrium.

91 8 91. A cable is attached to the plate B of mass M B, passes over a fixed peg at C, and is attached to the block at A. Using the coefficients of static friction shown, determine the smallest mass of block A so that it will prevent sliding motion of B down the plane. Given: M B 20 kg A deg B 0.3 g 9.81 m s 2 C 0.3 Solution: Iniitial guesses: T 1 1N T 2 1N N A 1N N B 1N M A 1kg Given Block A: Plate B: F x = 0; T 1 A N A M A g sin 0 F y = 0; N A M A g cos 0 F x = 0; T 2 M B g sin B N B A N A 0 F y = 0; N B N A M B g cos 0 Peg C: T 2 T 1 e C T 1 T 2 N A N B M A Find T 1 T 2 N A N B M A M A 2.22 kg

92 .

93 .

94 8 94. Block A has mass m A and rests on surface B for which the coefficient of static friction is sab. If the coefficient of static friction between the cord and the fixed peg at C is sc, determine the greatest mass m D of the suspended cylinder D without causing motion. Given: m A 50 kg sab 0.25 sc 0.3 a b c 0.3 m 0.25 m 0.4 m d 3 f 4 g 9.81 m s 2 Solution: Assume block A slips but does not tip. atan f d The initial guesses: N B 100 N T 50 N m D 1kg x 10 mm Given m D g Te sc d f 2 d 2 T m A g N B 0 f f 2 d 2 T sab N B 0 f f 2 d 2 Ta d f 2 d 2 T b 2 N B x 0 N B T m D x Find N B T m D x N B T N m D 25.6 kg x m Since x 51.6 mm < b mm our assumption is correct m D 25.6 kg

95 8 95. Block A rests on the surface for which the coefficient of friction is sab. If the mass of the suspended cylinder is m D, determine the smallest mass m A of block A so that it does not slip or tip. The coefficient of static friction between the cord and the fixed peg at C is sc. Units Used: g 9.81 m s 2 Given: sab 0.25 m D 4kg sc 0.3 a b c 0.3 m 0.25 m 0.4 m d 3 f 4 Solution: Assume that slipping is the crtitical motion atan f d The initial guesses: N B 100 N T 50 N m A 1kg x 10 mm Given m D g Te sc d f 2 d 2 T m A g N B 0 f f 2 d 2 T sab N B 0 f f 2 d 2 Ta d f 2 d 2 T b 2 N B x 0 N B T m A x Since x Find N B T m A x 51.6 mm < b 2 N B T N m A 7.82 kg x m 125 mm our assumption is correct m A 7.82 kg

96 .

97 8 97. Determine the smallest force P required to lift the 40-kg crate. The coefficient of static friction between the cable and each peg is m s = 0.1. A 200 mm 200 mm C 200 mm B Since the crate is on the verge of ascending, T 1 = 40(9.81) N and T 2 = P. From the geometry shown in Figs. a and b, the total angle the rope makes when in contact with the peg is b = 2b 1 + b 2 = 2a pb + a = 2p rad. Thus, pb P T 2 = T 1 e m s b P = 40(9.81)e 0.1(2p) = 736 N

98 8 98. Show that the frictional relationship between the belt tensions, the coefficient of friction m, and the angular contacts a and b for the V-belt is T 2 = T 1 e mb>sin(a>2). Impending motion b a T 2 T 1 FBD of a section of the belt is shown. Proceeding in the general manner: F x = 0; -(T + dt) cos du 2 F y = 0; -(T + dt) sin du 2 + T cos du df = 0 - T sin du dn sin a 2 = 0 Replace sin du du by, 2 2 cos du 2 df = m dn Using this and (dt)(du) : 0, the above relations become dt = 2m dn by 1, Tdu = 2adN sin a 2 b Combine dt T = m du sin a 2 Integrate from u = 0, T = T 1 to u = b, T = T 2 we get, mb T 2 = T 1 e sin a 2 Q.E.D

99 8 99. If a force of P = 200 N is applied to the handle of the bell crank, determine the maximum torque M that can be resisted so that the flywheel does not rotate clockwise. The coefficient of static friction between the brake band and the rim of the wheel is m s = 0.3. P 900 mm Referring to the free-body diagram of the bell crane shown in Fig. a and the flywheel shown in Fig. b, we have 400 mm A C B 100 mm a + M B = 0; T A (0.3) + T C (0.1) - 200(1) = 0 (1) O M a + M O = 0; T A (0.4) - T C (0.4) - M = 0 (2) By considering the friction between the brake band and the rim of the wheel where b = 270 p = 1.5 p rad and T A 7 T C, we can write mm T A = T C e m sb T A = T C e 0.3(1.5p) T A = T C (3) Solving Eqs. (1), (2), and (3) yields M = 187 N # m T A = N T C = N

100 A 10-kg cylinder D, which is attached to a small pulley B,is placed on the cord as shown. Determine the largest angle u so that the cord does not slip over the peg at C. The cylinder at E also has a mass of 10 kg, and the coefficient of static friction between the cord and the peg is m s = 0.1. A u B u C Since pully B is smooth, the tension in the cord between pegs A and C remains constant. Referring to the free-body diagram of the joint B shown in Fig. a, we have + c F y = 0; In the case where cylinder E is on the verge of ascending, T p 1 = 10(9.81) N. Here,, Fig. b. Thus, 2 + u ln Solving by trial and error, yields In the case where cylinder E is on the verge of descending, T 2 = 10(9.81) N and p T 1 =. Here,. Thus, sin u 2 + u T 2 = T 1 e m sb 10(9.81) = sin u e Solving by trial and error, yields 2T sin u - 10(9.81) = 0 T 2 = T 1 e m s b sin u = 10(9.81) e 0.1 a p 2 + ub 0.5 sin u = 0.1a p 2 + ub u = rad = a p 2 + ub ln (2 sin u) = 0.1a p 2 + ub u = rad = 38.8 Thus, the range of u at which the wire does not slip over peg C is u T = sin u T 2 = T = sin u and D E u max = 38.8

101 A V-belt is used to connect the hub A of the motor to wheel B. If the belt can withstand a maximum tension of 1200 N, determine the largest mass of cylinder C that can be lifted and the corresponding torque M that must be supplied to A.The coefficient of static friction between the hub and the belt is m s = 0.3, and between the wheel and the belt is m s =0.20. Hint: See Prob mm M A 200 mm 300 mm a B In this case, the maximum tension in the belt is T 2 = 1200 N. Referring to the freebody diagram of hub A, shown in Fig. a and the wheel B shown in Fig. b, we have a+ M O = 0; a+ M O = 0; T 1 = 6.54M C If hub A is on the verge of slipping, then T 1 = N M + T 1 (0.15) (0.15) = 0 M = 0.15( T 1 ) 1200(0.3) - T 1 (0.3) - M C (9.81)(0.2) = T 2 = T 1 e m s b 1 >sin(a>2) where b 1 = a bp = p rad (0.9167p)>sin = T 1 e (1) (2) C Substituting T 1 = N into Eq. (2), yields M C = kg If wheel B is on the verge of slipping, then T 2 = T 1 e m s b 1 >sin(a>2) 0.2(1.0833p)>sin = T 1 e T 1 = N Substituting T 1 = N into Eq. (2), yields where b 2 = a bp = p rad 180 M C = kg = 136 kg (controls!) Substituting T 1 = N into Eq. (1), we obtain M = 0.15( ) = 134 N # m

102 The 20-kg motor has a center of gravity at G and is pinconnected at C to maintain a tension in the drive belt. Determine the smallest counterclockwise twist or torque M that must be supplied by the motor to turn the disk B if wheel A locks and causes the belt to slip over the disk. No slipping occurs at A. The coefficient of static friction between the belt and the disk is m s = A 50 mm C B G M 50 mm 150 mm 100 mm Equations of Equilibrium: From FBD (a), a + M C = 0; T T = 0 (1) From FBD (b), a + M O = 0; M + T T = 0 (2) Frictional Force on Flat Belt: Here, b = 180 = p rad. Applying Eq. 8 6, T 2 = T 1 e mb, we have T 2 = T 1 e 0.3p = 3.003T 1 Solving Eqs. (1), (2), and (3) yields M = 3.93 N m # (3) T 1 = N T 2 = N

103 Blocks A and B have a mass of 100 kg and 150 kg, respectively. If the coefficient of static friction between A and B and between B and C is m s = 0.25 and between the ropes and the pegs D and E m s = 0.5 determine the smallest force F needed to cause motion of block B if P = 30 N. D A B 45 E P C F Assume no slipping between A and B. Peg D : T 2 = T 1 e mb ; F AD = 30 e 0.5(p 2 ) = N Block B : : + F x = 0; + c F y = 0; N BC + F BE cos 45 = 0 N BC F BE sin (9.81) = 0 F BE = N N BC = N Peg E : T 2 = T 1 e mb ; F = 768.1e 0.5(3p 4 ) = 2.49 kn Note: Since B moves to the right, (F AB ) max = 0.25 (981) = N = P max e 0.5(p 2 ) P max = 112 N 7 30 N Hence, no slipping occurs between A and B as originally assumed.

104 Determine the minimum coefficient of static friction m s between the cable and the peg and the placement d of the 3-kN force for the uniform 100-kg beam to maintain equilibrium. B 3 kn Referring to the free-body diagram of the beam shown in Fig. a, we have A 45 d 60 C : + F x = 0; T AB cos 45 - T BC cos 60 = 0 6 m + c F y = 0; a+ M A = 0; Solving, T AB sin 45 + T BC sin (9.81) 1000 T BC sin 60 (6) - 100(9.81) (3) - 3d = = 0 d = 4.07 m T BC = kn T AB = kn Using the results for T BC and T AB and considering the friction between the cable and the peg, where b = ca bp d = p rad, we have 180 T BC = T AB e m sb = e m s(0.5833p) ln = m s (0.5833p) m s = 0.189

105 A conveyer belt is used to transfer granular material and the frictional resistance on the top of the belt is F = 500 N. Determine the smallest stretch of the spring attached to the moveable axle of the idle pulley B so that the belt does not slip at the drive pulley A when the torque M is applied. What minimum torque M is required to keep the belt moving? The coefficient of static friction between the belt and the wheel at A is m s = m A M F = 500 N B 0.1 m k =4kN/m Frictional Force on Flat Belt: Here, b = 180 = p rad and T 2 = T and T 1 = T. Applying Eq. 8 6, we have T 2 = T 1 e mb T = Te 0.2p T = N Equations of Equilibrium: From FBD (a), a+ M O = 0; M = 0 M = 50.0 N # m From FBD (b), : + F x = 0; F sp = 0 F sp = N Thus, the spring stretch is x = F sp k = = m = 286 mm

106 The belt on the portable dryer wraps around the drum D, idler pulley A, and motor pulley B. If the motor can develop a maximum torque of M = 0.80 N # m, determine the smallest spring tension required to hold the belt from slipping. The coefficient of static friction between the belt and the drum and motor pulley is m s = 0.3. Ignore the size of the idler pulley A. B M = 0.8 N m 50 mm 45 A 30 D a+ M B = 0; T 2 = T 1 e mb ; -T T = 0 T 2 = T 1 e p2 = T 1 20 mm C 50 mm T 1 = N T 2 = N a+ M C = 0; F s = 85.4 N -F s sin cos cos sin 45 2 = 0

107 P = 2000 N. 50 mm 75 mm P = 2000 N, we have R 2 = 37.5 mm, R 1 = 25 mm, µ 3 = = 3 (0.3)(2000) = Nmm = 19 Nm 2 2

108 P = 2000 N 3.6 N m R 2 = 37.5 mm, R 1 = 25 mm, M = 3.6 (1000) = 3600 N mm and P = 2000 N, we have = 3 ( )(2000) k mm 75 mm μ k =

109 4000 N. If µ s = 0.35, mm 50 mm P = 4000 N = 3 (0.35)(4000) mm = Nmm M = 54.4 N m

110 The shaft is supported by a thrust bearing A and a journal bearing B. Determine the torque M required to rotate the shaft at constant angular velocity.the coefficient of kinetic friction at the thrust bearing is m k = 0.2. Neglect friction at B. a A a M B P 4 kn 75 mm 150 mm Applying Eq. 8 7 with R R 2 = = = m, = m, m s = and P = 4000 N, we have Section a-a M = 2 3 m sp R R 1 3 R R 1 2 = )a b = 46.7 N # m

111 The thrust bearing supports an axial load of P = 6 kn. If a torque of M = 150 N # m is required to rotate the shaft, determine the coefficient of static friction at the constant surface. 200 mm 100 mm Applying Eq. 8 7 with R R2 = 0.2 m 1 = 0.1 m = 0.05 m, = 0.1 m, M = 150 N # m 2 2 and P = 6000 N, we have M M = 2 3 m sp R R 1 3 R R = 2 3 m s16000)a b m s = P

112 Assuming that the variation of pressure at the bottom of the pivot bearing is defined as p = p 0 1R 2 >r2, determine the torque M needed to overcome friction if the shaft is subjected to an axial force P. The coefficient of static friction is m s. For the solution, it is necessary to determine in terms of P and the bearing dimensions and. p 0 R 1 R 2 P M F z = 0; P = LA dn = L 2p M z = 0; M = LA rdf = L 2p Using Eq. (1): = L 2p 0 L = L 2p R 2 = 2p p 0 R 2 (R 2 - R 1 ) P Thus, p 0 = C2pR 2 (R 2 - R 1 )D 0 L R 2 R 2 0 LR 1 p 0 a R 2 b rdr du R 1 r R 2 0 LR 1 pr dr du m s pr 2 dr du m s p 0 a R 2 R 1 r br2 dr du = m s (2p p 0 ) R AR2 2 - R 2 1B R 2 R1 r p 0 p p 0 R 2 r M = 1 2 m s P (R 2 + R 1 )

113 The plate clutch consists of a flat plate A that slides over the rotating shaft S. The shaft is fixed to the driving plate gear B. If the gear C, which is in mesh with B, is subjected to a torque of M = 0.8N # m, determine the smallest force P, that must be applied via the control arm, to stop the rotation. The coefficient of static friction between the plates A and D is m s = 0.4. Assume the bearing pressure between A and D to be uniform. F A D 100 mm S 125 mm P 200 mm 150 mm F = = N 150 mm E B 30 mm M = (0.150) = 4.00 N # m M 0.8 N m M = 2 3 m P a R3 2 - R 3 1 R R 2 b 1 C 4.00 = 2 3 (0.4) (P )a (0.125)3 - (0.1) 3 (0.125) 2 - (0.1) 2 b P = N a+ M F = 0; (0.2) - P(0.15) = 0 P = 118 N

114 The conical bearing is subjected to a constant pressure distribution at its surface of contact. If the coefficient of static friction is m s, determine the torque M required to overcome friction if the shaft supports an axial force P. P M R The differential area (shaded) da = 2pr dr cos u = 2prdr cos u P = p cos u da = p cos u 2prdr L L cos u = 2pp rdr L0 R u P = ppr 2 p = P pr 2 dn = pda = P pr 2prdr 2 cos u = 2P R 2 cos u rdr M = L rdf = L m s rdn = R 2m s P R 2 r 2 dr cos u L0 = 2m s P R 3 R 2 cos u 3 = 2m s PR 3 cos u

115 The pivot bearing is subjected to a pressure distribution at its surface of contact which varies as shown. If the coefficient of static friction is m, determine the torque M required to overcome friction if the shaft supports an axial force P. P M df = m dn = m p 0 cos a pr 2R b da r R M = rm p 0 cos a pr b rdr du LA 2R R = m p 0 ar 2 cos a pr L 0 2R bdrb L0 = m p 0 B 2r A p 2R B 2 = mp 0 16R3 p 2 cap 2 b 2-2 d = m p 0 R 3 R P = dn = p 0 acos a pr LA L 0 2R brdrb L0 = p 0 B 1 A p 2R B 2 = 4p 0 R 2 a1-2 p b pr A p cos a 2R b + 2R B 2 r 2-2 A p 2R B 3 pr cos a 2R b + 2p du 2p du R r sin a pr A p 2R B 2R b R 12p2 0 R sin a pr 2R bd 12p2 0 p 0 π r p=p 0 cos 2R = 1.454p 0 R 2 Thus, M = PmR

116 A 200-mm diameter post is driven 3 m into sand for which m s = 0.3. If the normal pressure acting completely around the post varies linearly with depth as shown, determine the frictional torque M that must be overcome to rotate the post. M 200 mm 3m Equations of Equilibrium and Friction: The resultant normal force on the post is N = p = 180p N. 2 F = m s N = p2 = 54.0p N. Since the post is on the verge of rotating, 600 Pa a+ M O = 0; M p10.12 = 0 M = 17.0 N # m

117 A beam having a uniform weight W rests on the rough horizontal surface having a coefficient of static friction m s. If the horizontal force P is applied perpendicular to the beam s length, determine the location d of the point O about which the beam begins to rotate. 1 3 L P 2 3 L O d w = m sn L F z = 0; N = W F x = 0; P + m s Nd L - m s N(L - d) = 0 L M Oz = 0; m s N(L - d) 2 2L + m s Nd 2 2L - P a 2L 3 - db = 0 m s W(L - d) 2 2L + m swd 2 2L - a 2L 3 - dbam s W(L - d) - m s Wd L L b = 0 3(L - d) 2 + 3d 2-2(2L - 3d)(L - 2d) = 0 6d 2-8Ld + L 2 = 0 Choose the root 6 L. d = L

118 a 20-mm-diameter pin at B and to the crank shaft by a 50-mm-diameter bearing A. If the piston is moving 50(0.2) = =5mm 2 20(0.2) = = 2mm 2

119 ..

120 A pulley of mass M has radius a and the axle has a diameter D. If the coefficient of kinetic friction between the axle and the pulley is k determine the vertical force P on the rope required to lift the block of mass M B at constant velocity. Given: a M D 120 mm 5kg 40 mm k 0.15 M B 80 kg Solution: k atan k r f D 2 sin k M p = 0; Mgr f M B gar f Par f 0 P Mgr f M B gar f P 826 N a r f

121 A pulley of mass M has radius a and the axle has a diameter D. If the coefficient of kinetic friction between the axle and the pulley is k determine the force P on the rope required to lift the block of mass M B at constant velocity. Apply the force P horizontally to the right (not as shown in the figure). Given: a 120 mm M D 5kg 40 mm k 0.15 M B 80 kg Solution: g 9.81 m s 2 k atan k r f D 2 sin k Guesses P Given 1N R 1N 1 deg R cos M B g P Rsin 0 Mg 0 M B ga Pa Rr f 0 P R Find P R P 814 N

122 The collar fits loosely around a fixed shaft that has radius r. If the coefficient of kinetic friction between the shaft and the collar is k, determine the force P on the horizontal segment of the belt so that the collar rotates counterclockwise with a constant angular velocity. Assume that the belt does not slip on the collar; rather, the collar slips on the shaft. Neglect the weight and thickness of the belt and collar. The radius, measured from the center of the collar to the mean thickness of the belt is R. Given: r 50mm k 0.3 R 56.25mm F 100N Solution: k atan k k deg Equilibrium : r f r sin k r f mm F y = 0; R y F = 0 R y F R y N F x = 0; P R x = 0 R x = P 2 2 R = R x R y = P 2 F 2 Guess P 1N Given P 2 F 2 r f FR PR 0 = P Find( P) P N

123 The collar fits loosely around a fixed shaft that has radius r. If the coefficient of kinetic friction between the shaft and the collar is k, determine the force P on the horizontal segment of the belt so that the collar rotates clockwise with a constant angular velocity. Assume that the belt does not slip on the collar; rather, the collar slips on the shaft. Neglect the weight and thickness of the belt and collar. The radius, measured from the center of the collar to the mean thickness of the belt is R. Given: r 50mm k 0.3 R 56.25mm F 100N Solution: k atan k k deg Equilibrium : r f r sin k r f mm F y = 0; R y F = 0 R y F R y N F x = 0; P R x = 0 R x = P 2 2 R = R x R y = P 2 F 2 Guess P 1N Given P 2 F 2 r f FR PR 0 = P Find( P) P N

124 A pulley having a diameter of 80 mm and mass of 1.25 kg is supported loosely on a shaft having a diameter of 20 mm. Determine the torque M that must be applied to the pulley to cause it to rotate with constant motion. The coefficient of kinetic friction between the shaft and pulley is m k = 0.4. Also calculate the angle u which the normal force at the point of contact makes with the horizontal. The shaft itself cannot rotate. Frictional Force on Journal Bearing: Here, f k = tan -1 m k = tan = Then the radius of friction circle is r f = r sin f k = 0.01 sin = m. The angle which the normal force makes with horizontal is 40 mm M u = 90 - f k = 68.2 Equations of Equilibrium: + c F y = 0; R = 0 R = N a+ M O = 0; M = 0 M = N # m

125 The 5-kg skateboard rolls down the 5 slope at constant speed. If the coefficient of kinetic friction between the 12.5 mm diameter axles and the wheels is m k = 0.3, determine the radius of the wheels. Neglect rolling resistance of the wheels on the surface. The center of mass for the skateboard is at G. 75 mm G mm 300 mm Referring to the free-body diagram of the skateboard shown in Fig. a, we have F x = 0; F y = 0; The effect of the forces acting on the wheels can be represented as if these forces are acting on a single wheel as indicated on the free-body diagram shown in Fig. b.we have F x = 0; F y = 0; Thus, the magnitude of R is R = 2R x 2 + R y 2 = = N f s = tan -1 m s = tan -1 (0.3) = Thus, the moment arm of R from point O is (6.25 sin ) mm. Using these results and writing the moment equation about point O,Fig.b, we have a+ M O = 0; F s - 5(9.81) sin 5 = 0 N - 5(9.81) cos 5 = 0 R x = R y = 0 F s = N N = N R x = N R y = N 4.275(r) (6.25 sin = 0) r = 20.6 mm

126 Determine the force P required to overcome rolling resistance and pull the 50-kg roller up the inclined plane with constant velocity. The coefficient of rolling resistance is a = 15 mm. P 300 mm 30 30

127 Determine the force P required to overcome rolling resistance and support the 50-kg roller if it rolls down the inclined plane with constant velocity. The coefficient of rolling resistance is a = 15 mm. P 300 mm 30 30

128 The lawn roller has mass M. If the arm BA is held at angle from the horizontal and the coefficient of rolling resistance for the roller is r, determine the force P needed to push roller at constant speed. Neglect friction developed at the axle, A, and assume that the resultant force P acting on the handle is applied along arm BA. Given: M 80 kg 30 deg a r 250 mm 25 mm Solution: 1 asin r a deg M 0 = 0; rmg Psinr P cosa cos 1 0 P sin rmg r cos a cos 1 P 96.7 N

129 A machine of mass M is to be moved over a level surface using a series of rollers for which the coefficient of rolling resistance is a g at the ground and a m at the bottom surface of the machine. Determine the appropriate diameter of the rollers so that the machine can be pushed forward with a horizontal force P. Hint: Use the result of Prob Units Used: Mg Given: 1000 kg M a g 1.4 Mg 0.5 mm a m 0.2 mm P 250 N Solution: P Mga g a m 2 r r Mg a g a m r 19.2 mm d 2 r d 38.5 mm 2 P

130 The hand cart has wheels with a diameter of 80 mm. If a crate having a mass of 500 kg is placed on the cart so that each wheel carries an equal load, determine the horizontal force P that must be applied to the handle to overcome the rolling resistance. The coefficient of rolling resistance is 2 mm. Neglect the mass of the cart. P P L Wa r = a 2 40 b P = 245 N

131 The cylinder is subjected to a load that has a weight W. If the coefficients of rolling resistance for the cylinder s top and bottom surfaces are a A and a B, respectively, show that a horizontal force having a magnitude of P = [W(a A + a B )]>2r is required to move the load and thereby roll the cylinder forward. Neglect the weight of the cylinder. : + F x = 0; (R A ) x - P = 0 (R A ) x = P + c F y = 0; (R A ) y - W = 0 (R A ) y = W a + M B = 0; P(r cos f A + r cos f B ) - W(a A + a B ) = 0 (1) f A f B Since and are very small, cos f A - cos f B = 1. Hence, from Eq. (1) P W A r B P = W(a A + a B ) 2r (QED)

132 A large crate having a mass of 200 kg is moved along the floor using a series of 150-mm-diameter rollers for which the coefficient of rolling resistance is 3 mm at the ground and 7 mm at the bottom surface of the crate. Determine the horizontal force P needed to push the crate forward at a constant speed. Hint: Use the result of Prob P Rolling Resistance: Applying the result obtained in Prob P = W1a A + a B 2, 2r with a A = 7 mm, a B = 3 mm, W = = 1962 N, and r = 75 mm, we have P = = N = 131 N

133 Each of the cylinders has a mass of 50 kg. If the coefficients of static friction at the points of contact are m A = 0.5, m B = 0.5, m C = 0.5, and m D = 0.6, determine the smallest couple moment M needed to rotate cylinder E. A 300 mm D M E 300 mm B C.

134 The clamp is used to tighten the connection between two concrete drain pipes. Determine the least coefficient of static friction at A or B so that the clamp does not slip regardless of the force in the shaft CD. 250 mm 100 mm A C B D

135 If P = 900 N is applied to the handle of the bell crank, determine the maximum torque M the cone clutch can transmit. The coefficient of static friction at the contacting surface is m s = mm mm C M 200 mm B A Referring to the free-body diagram of the bellcrank shown in Fig. a,we have a + M B = 0; 900(0.375) - F C (0.2) = 0 F C = N Using this result and referring to the free-body diagram of the cone clutch shown in Fig. b, 375 mm P : + F x = 0; 2 N sin = 0 N = N 2 The area of the differential element shown shaded in Fig. c is dr da = 2pr ds = 2pr. Thus, sin 15 = 2p sin 15 rdr A = LA da = L 0.15 m surface is m 2p rdr = m2. The pressure acting on the cone sin 15 p = N A = = 78.13(103 ) N > m 2 The normal force acting on the differential element d A is dn = pda = 78.13(10 3 2p )c. sin 15 drdr = (103 )rdr Thus, the frictional force acting on this differential element is given by df = m s dn = 0.3( )(10 3 )rdr = (10 3 )rdr. The moment equation about the axle of the cone clutch gives M = 0; M - rdf = 0 L 0.15 m M = rdf = (10 3 ) r 2 dr L L m M = 270 N # m

136 The lawn roller has a mass of 80 kg. If the arm BA is held at an angle of 30 from the horizontal and the coefficient of rolling resistance for the roller is 30 mm, determine the force P needed to push the roller at constant speed. Neglect friction developed at the axle, A, and assume that the resultant force P acting on the handle is applied along arm BA. 250 mm B P A 30 u = sin a b = a+ M O = 0; -30(784.8) - P sin 30 (30) + P cos 30 (250 cos ) = 0 Solving, P = N 30mm

SOLUTION 8 7. To hold lever: a+ M O = 0; F B (0.15) - 5 = 0; F B = N. Require = N N B = N 0.3. Lever,

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