The two pipes are made of the steel (E=210GPa, oy=420MPA) material and are connected as shown in Figure 3 and loaded by a force P at point C. The cross-sectional area of AC and CB are 600 mm2 and 900 mm2 , respectively. The length of AC and CB are same a=b= (see attached file) m. If AC becomes plastic, determine a) the displacement of the step, b) the ultimate load of the stepped bar, c) draw a load-deflection diagram for the sectional area of AC and CB. (Consider a material as an elastic-perfectly plastic material) a=12,9m b=12,9m a C

The two pipes are made of the steel (E=210GPa, oy=420MPA) material and are connected as shown in Figure 3 and loaded by a force P at point C. The cross-sectional area of AC and CB are 600 mm2 and 900 mm2 , respectively. The length of AC and CB are same a=b= (see attached file) m. If AC becomes plastic, determine a) the displacement of the step, b) the ultimate load of the stepped bar, c) draw a load-deflection diagram for the sectional area of AC and CB. (Consider a material as an elastic-perfectly plastic material) a=12,9m b=12,9m a C

Structural Analysis

6th Edition

ISBN:9781337630931

Author:KASSIMALI, Aslam.

Publisher:KASSIMALI, Aslam.

Chapter2: Loads On Structures

Section: Chapter Questions

Problem 1P

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Concept explainers

Open Channel Flow

Open channel flow is a branch of fluid mechanics. It deals with the flow of fluid in an open conduit or free surface. In an open channel flow, gravity induces the flow of water whose surface is open to the air. This flow is free-falling rather than confined in rigid body conduits. The open channel flow depends upon two parameters that are the cross-section of the conduit and the velocity profile. Practical examples of open channel flow are streams, rivers, canals, and other drainage systems.In open channel flow, the cross-sectional area of at least one of the sides is exposed to air, and the surface of water faces atmospheric pressure. This flow is also known as free gravity flow. The cross-sectional area of the conduit can be either man-made or a natural channel. For instance, the flow in rivers and streams are natural conduits, and the flow in a canal and sanitary systems are man-made or engineered channels.

Question

The two pipes are made of the steel
(E=210GPA, o=420MPA)
material and are
connected as shown in Figure 3 and loaded
by a force P at point C. The cross-sectional
area of AC and CB are 600 mm2 and 900
mm2 , respectively. The length of AC and CB
are same a=b= (see attached file) m. If AC
becomes plastic, determine a) the
displacement of the step,
b) the ultimate load of the stepped bar,
c) draw a load-deflection diagram for the
sectional area of AC and CB. (Consider a
material as an elastic-perfectly plastic
material)
a=12,9m b=12,9m
a
B
Figure 3

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