Cords are loop around a small spacer separating two cylinders each weighing 400 kg and pass, as shown in figure over a frictionless pulleys to weights of 200kg and 400 kg. Determine the angle 0 and the normal pressure N between the cylinders and the smooth horizontal surface.

Cords are loop around a small spacer separating two cylinders each weighing 400 kg and pass, as shown in figure over a frictionless pulleys to weights of 200kg and 400 kg. Determine the angle 0 and the normal pressure N between the cylinders and the smooth horizontal surface.

Name: Cords are loop around a small spacer separating two cylinders each we
Uploaded: 2024-03-20T06:56:55.000Z
Channel: Bartleby
Description: Cords are loop around a small spacer separating two cylinders each weighing 400 kg and pass, asshown in figure over a frictionless pulleys to weights of 200kg and 400 kg. Determine theangle and the normal pressure N between the cylinders and the smo

International Edition---engineering Mechanics: Statics, 4th Edition

4th Edition

ISBN:9781305501607

Author:Andrew Pytel And Jaan Kiusalaas

Publisher:Andrew Pytel And Jaan Kiusalaas

Chapter8: Centroids And Distributed Loads

Section: Chapter Questions

Problem 8.122P: The 12-ft wide quarter-circular gate AB is hinged at A. Determine the contact force between the gate...

See similar textbooks

Similar questions

The 12-ft wide quarter-circular gate AB is hinged at A. Determine the contact force between the gate and the smooth surface at B due to water pressure acting on the gate. Use =62.4lb/ft3 for water.
The weight of the cylindrical tank is negligible in comparison to the weight of water it contains (water weighs 62.4lb/ft3). The coefficient of static friction between the tank and the horizontal surface is s. (a) Assuming a full tank, find the smallest force P required to tip the tank, and the smallest s that would allow tipping to take place. (b) If the force P = 200 lb initiates tipping, determine the depth of water in the tank.
Cords are looped around a small spacer separating two cylinder each weighing 400kn and pass over a frictionless pulleys to weights of 200KN and 400kn. Determine the angle and the pressure N between the cylinder and smooth horizontal surface
The strength per meter of the longitudinal joint in the figure is 480 kN, whereas or the girth joint is 200 kN. Determine the maximum diameter of the cylindrical tank if the internal pressure is 1.5 MPa.
It is required to determine the maximum force FT required to hold the inflatable flood control barrier in place assuming it has been filled with air to a gauge pressure of P = 12.0 kPa. The barrier has an average diameter of d = 950 mm and its maximum individual length is L = 12.0 m. Since this force is the one acting on the part of the non-inflatable membrane that receives the flood water (seen on the left side of Figure 1), use the value of FT that you obtained to calculate the mean stress srip [MPa ] that is acting on that membrane assuming it has an effective thickness of t = 2.5 mm.
Q 244 What are the reaction forces on the latch an djoint in the gate below? And in case thefloodgate is reversed (concave)? *The gate is a cylinder room with length L = 5 m
The weight of the motorcycle is 151 kg and the weight of the driver is 64 kg. Dimensions: l1 = 0,31 m and l2 = 0,23 m Determine the required frictional force.
5.) A lO-kN car and 5-kN hoist are supported 1.8 m above the floor by a cylinder with a 300-mm bore . What pressure will this develop in the system?
8. In a hot air balloon launch, it was known that the material used in the construction amounts to 200kg and that the loading capacity of the cage was 250kg. If the hot air balloon has to travel in air where the ambient temperature and pressure was 25°C and 101.325kPaa, determine the minimum diameter (meters) of the balloon (assume to be spherical) needed to course the air if the setting temperature of hot air inside the balloons is 80°C. Assume pressure inside the balloon to be atmospheric. Draw a figure or FBD that will support the problem. Explain each step by step formula.
The test tube opens at 293 K with 13 cm Hg at the bottom, and 5.6 cm water above Hg. Calculate the pressure at the bottom of the tube if the atmospheric pressure is 760 mm Hg. Use a density of 13.55 g / cm3 for Hg and 0.998 g / cm3 for water. Give answers in terms of dyne / cm2, psia, and kN / m2 • (See conversion table). = kPa. = ..... dyne / cm2. = .... psia = ....
at the bottom of a container, which forms an angle A with the horizontal, is a cube of edge a, as shown in the figure, made of a material of density p. Determine the force with which the cube presses on the bottom, if a liquid of density p0 is poured into the container. The top edge of the cube is h from the surface of the liquid. There is no liquid between the bottom of the container and the cube. The atmospheric pressure is P and the acceleration of gravity g (neglect the thrust).
A water tank 3m in diameter and 6m high is made from 12mm thickness of steel. When the tank is filled with water: - Determine the circumferential stress - And the tension force in the vessel