10:21Equilibrium of a Particle (2D x-y plane forces) | Mechanics Statics | (Learn to solve any question)Question Solutions1197views
10:22Mechanical Engineering: Particle Equilibrium (7 of 19) Tension of Cables Attached to Hanging ObjectMichel van Biezen641views
05:35AP Physics 1: Equilibrium 5: Static Equilibrium Problem 4: Object Hung by 3 CablesYau-Jong Twu1189views
11:32Equilibrium of Rigid Bodies (2D - Coplanar Forces) | Mechanics Statics | (Solved examples)Question Solutions1121views
Multiple ChoiceA board 8 m in length, 20 kg in mass, and of uniform mass distribution, is supported by two scales placed underneath it. The left scale is placed 2 m from the left end of the board, and the right scale is placed on the board's right end. A small object 10 kg in mass is placed on the left end of the board. Calculate the reading on the left scale. (Use g=10 m/s2.)BONUS:Calculate the reading on the right scale.463views6rank4comments
Textbook QuestionA diving board 3.00 m long is supported at a point 1.00 m from the end, and a diver weighing 500 N stands at the free end (Fig. E11.11). The diving board is of uniform cross section and weighs 280 N. Find (a) the force at the support point.792views1rank
Textbook QuestionA 350-N, uniform, 1.50-m bar is suspended horizontally by two vertical cables at each end. Cable A can support a maximum tension of 500.0 N without breaking, and cable B can support up to 400.0 N. You want to place a small weight on this bar. (a) What is the heaviest weight you can put on without breaking either cable, and (b) where should you put this weight?746views
Textbook QuestionA person's center of mass is easily found by having the person lie on a reaction board. A horizontal, 2.5-m-long, 6.1 kg reaction board is supported only at the ends, with one end resting on a scale and the other on a pivot. A 60 kg woman lies on the reaction board with her feet over the pivot. The scale reads 25 kg. What is the distance from the woman's feet to her center of mass?293views
Textbook Question(II) A shop sign weighing 215 N hangs from the end of a uniform 135-N beam as shown in Fig. 12–59. Find the tension in the supporting wire (at 35.0°), and the horizontal and vertical forces exerted by the hinge on the beam at the wall.<IMAGE>197views
Textbook Question(III) Two wires run from the top of a pole 2.6 m tall that supports a volleyball net. The two wires are anchored to the ground 2.0 m apart, and each is 2.0 m from the pole (Fig. 12–70). The tension in each wire is 125 N. What is the tension in the net, assumed horizontal and attached at the top of the pole?<IMAGE>156views
Textbook Question(II) A heavy load M g = 62.0 kN hangs at point E of the single cantilever truss shown in Fig. 12–81.(a) Use a torque equation for the truss as a whole to determine the tension F_T in the support cable, and then determine the force F→_A on the truss at pin A. Neglect the weight of the trusses, which is small compared to the load.<IMAGE>131views
Textbook QuestionThe roof over a 9.0-m x 10.0-m room in a school has a total mass of 12,400 kg. The roof is to be supported by vertical wooden “2 x 4s” (2 x4 in inches, but actually about 4.0 x 9.0 cm) equally spaced along the 10.0-m sides. How many supports are required on each side, and how far apart must they be? Consider only compression, and assume a safety factor of 12.138views
Textbook QuestionTwo springs, both having stiffness constant 225 N/m, are attached to a table and to a 0.500-kg uniform thin wooden board (Fig. 12–98). The board is exactly horizontal. What are the natural lengths of each spring? [Hint: One of the springs is stretched, the other compressed, from their natural equilibrium lengths.]<IMAGE>104views