Dynamics Hibbeler 15-31 Solution | Block A weighs 10 lb and block B weighs 3 lb. If B is moving down

Dynamics Hibbeler 15-30 Solution | A jet plane having a mass of 7 Mg takes off from an aircraft carr

Dynamics Hibbeler 14-77 Solution | The roller coaster car having a mass m is released from rest at p

Dynamics Hibbeler 14-75 Solution | The assembly consists of two blocks A and B, which have a mass of

Dynamics Hibbeler 14-91 Solution | When the 5-kg box reaches point A it has a speed vA = 10 m/s. Det

Dynamics Hibbeler 14-96 | If the 20-kg cylinder is released from rest at h = 0, determine the requir

Dynamics Hibbeler 13-13 Solution | Block A has a weight of 8 lb and block B has a weight of 6 lb. Th

Dynamics Hibbeler 13-11 Solution | Determine the time needed to pull the cord at B down 4 ft startin

Dynamics Hibbeler 13-5 Solution | If blocks A and B of mass 10 kg and 6 kg, respectively, are placed

Statics Hibbeler 4-11 Solution | The towline exerts a force of P = 6 kN at the end of the 8-m-long c

Dynamics Hibbeler 13-8 Solution | The speed of the 3500-lb sports car is plotted over the 30-s time

Statics Hibbeler 4-9 Solution | Determine the moment of each force about the bolt located at A. Take

Dynamics Hibbeler 13-7 Solution | The 10-lb block has a speed of 4 ft/s when the force of F = (8t^2)

Statics Hibbeler 4-5 Solution | Determine the moment about point B of each of the three forces actin

Dynamics Hibbeler 13-9 Solution | The conveyor belt is moving at 4 m/s. If the coefficient of static

Statics Hibbeler 4-4 Solution | Determine the moment about point A of each of the three forces actin

Dynamics Hibbeler 12-212 Solution | The girl at C stands near the edge of the pier and pulls in the

Statics Hibbeler 3-15 Solution | The unstretched length of spring AB is 3 m. If the block is held in

Dynamics Hibbeler 12-205 Solution | If block A of the pulley system is moving downward at 6 ft/s whi

Statics Hibbeler 3-7 Solution | The man attempts to pull down the tree using the cable and small pul

Dynamics Hibbeler 12-198 Solution | If the end of the cable at A is pulled down with a speed of 5 m/

Statics Hibbeler 3-1 Solution | The members of a truss are pin connected at joint O. Determine the m

Dynamics Hibbeler 13-38 Solution | The 300-kg bar B, originally at rest, is being towed over a serie

Statics Hibbeler 2-1 Solution | If theta = 60 degrees and F = 450 N, determine the magnitude of the

Dynamics Hibbeler 13-37 Solution | The 10-kg block A rests on the 50-kg plate B in the position show

Statics Hibbeler 1-1 Solution | Determine the weight in newtons of an object that has a mass of: (a)

Dynamics Hibbeler 17-119 Solution | The solid ball of radius r and mass m rolls without slipping dow

Dynamics Hibbeler 16-70 Solution | The angular velocity of link AB is omega_AB = 5 rad/s. Determine

Dynamics Hibbeler 18-42 Solution | The spool has a mass of 20 kg and a radius of gyration of kO = 16

Dynamics Hibbeler 16-69 Solution | Rod AB is rotating with an angular velocity of omega_AB = 60 rad/

Dynamics Hibbeler 16-68 Solution | Knowing that angular velocity of link AB is omega_AB = 4 rad/s, d

Dynamics Hibbeler 16-67 Solution | Determine the velocity of point A on the rim of the gear at the i

Dynamics Hibbeler 22-16 Solution | A block of mass m is suspended from two springs having a stiffnes

Dynamics Hibbeler 22-10 Solution | Determine the frequency of vibration for the block. The springs

Dynamics Hibbeler 22-7 Solution | A 2-lb weight is suspended from a spring having a stiffness k = 2

Dynamics Hibbeler 22-11 Solution | While standing in an elevator, the man holds a pendulum which con

Dynamics Hibbeler 22-1 Solution | A spring is stretched 175 mm by an 8-kg block. If the block is dis

Dynamics Hibbeler 21-1 Solution | Show that the sum of the moments of inertia of a body, Ixx + Iyy +

Dynamics Hibbeler 18-21 Solution | A yo-yo has a weight of 0.3 lb and a radius of gyration k_O = 0.0

Dynamics Hibbeler 18-20 Solution | If P = 200 N and the 15-kg uniform slender rod starts from rest

Dynamics Hibbeler 16-57 Solution | At the instant shown the boomerang has an angular velocity w = 4

Dynamics Hibbeler 16-1 Solution | The angular velocity of the disk is defined by w = (5t^2 + 2) rad/

Dynamics Hibbeler 16-8 Solution | If gear A rotates with an angular velocity of omega_A = (theta_A +

Dynamics Hibbeler 18-49 Solution | The assembly consists of two 10-kg bars which are pin connected.

Dynamics Hibbeler 20-1 Solution | The propeller of an airplane is rotating at a constant speed omega

Dynamics Hibbeler 19-57 Solution | A solid ball with a mass m is thrown on the ground such that at

Dynamics Hibbeler 19-1 Solution | The rigid body (slab) has a mass $m$ and rotates with an angular

Dynamics Hibbler 18-3 Solution | The wheel is made from a 5-kg thin ring and two 2-kg slender rods.

Dynamics Hibbeler 18-2 Solution | The wheel is made from a 5-kg thin ring and two 2-kg slender rods.

Dynamics Hibbeler 18-1 Solution | At a given instant the body of mass m has an angular velocity omeg

Dynamics Hibbeler 19-6 Solution | The 100-kg spool shown in Fig. 19-6a has a radius of gyration k_G

Dynamics Hibbeler 19-5 Solution | The 20-lb disk shown in Fig. 19-5a is acted upon by a constant

Dynamics Hibbeler 17-24 Solution | The door has a weight of 200 lb and a center of gravity at G.

Dynamics Hibbeler 17-92 Solution | The 10-kg semicircular disk is rotating at omega = 4 rad/s. At

Dynamics Hibbeler 17-108 Solution | A uniform rod having a weight of 10 lb is pin supported at A

Dynamics Hibbeler 17-106 Solution | The truck carries the spool which has a weight of 490 lb and a

Dynamics Hibbeler 17-94 Solution | The 75 kg wheel has a radius of gyration about its mass center G

Dynamics Hibbeler 17-90 Solution | The cord is wrapped around the inner core of the spool. If a 5 lb

Dynamics Hibbeler 17-93 Solution | The ship has a weight of 4 times 10^6 lb and center of gravity

Dynamics Hibbeler 12-6 Solution | The position of a particle along a straight line is given by s =