7.9 : Relation Between the Shear and Bending Moment

Suppose a beam is subjected to a distributed load, two concentrated loads, and a couple moment. Establish the relationship between the shear and the bending moment.

Consider an elemental section of the beam and draw a free-body diagram of the section.

For the section to be in equilibrium, the moment acting on the right side of the section should be higher by a small and finite amount.

A resultant force of the distributed load is exerted at a fractional distance from the section's right end.

Using the equilibrium equation for moment, a relation between moment and shear can be obtained.

Further, by dividing it by Δx and letting Δx approach zero, the slope of the moment diagram is determined, which is equivalent to the shear.

A maximum bending moment occurs at the point where the slope of the moment and the shear are zero.

Integrating the distributed load over the elemental section, lying between two arbitrary points, a correlation between the change in the bending moment and the area under the shear diagram is obtained.

When a beam is subjected to various loads, such as a distributed load, concentrated loads, and a couple moment, it experiences both shear forces and bending moments. To understand the relationship between these two forces, we can analyze an elemental section of the beam and draw a free-body diagram.

Static equilibrium diagram with force and moment analysis; ΔF=w(x)Δx, Δk=k(Δx), 0<k<1.

For the elemental section of the beam to be in equilibrium, the moment acting on the right side of the section should be higher by a small and finite amount compared to the left side. The distributed load exerts a resultant force at a fractional distance from the section's right end. We can use the equilibrium equation for moment to establish the relationship between the shear and bending moment.

Static equilibrium equation ΔM=VΔx−kw(x)Δx²; mechanical analysis formula.

By dividing this equation by Δx and letting Δx approach zero, we determine the slope of the moment diagram, which is equivalent to the shear.

Differential equation, dM/dx = V, illustrating static equilibrium concept.

By integrating the distributed load over the elemental section lying between two arbitrary points, we can correlate the change in the bending moment and the area under the shear diagram.

$Beams bending moment equation: \(M_C - M_B = \int_{x_B}^{x_C} V dx\), engineering diagram.$

This relationship is essential for understanding how the beam's internal forces respond to external loads and how these forces impact the beam's overall structural behavior.

Tags

Shear Force Bending Moment Beam Analysis Equilibrium Free body Diagram Distributed Load Concentrated Loads Couple Moment Moment Diagram Internal Forces Structural Behavior Load Response Integration

장에서 7:

article

Now Playing

7.9 : Relation Between the Shear and Bending Moment

Internal Forces

978 Views

article

7.1 : 서명 규약

Internal Forces

1.9K Views

article

7.2 : 법선 및 전단력

Internal Forces

2.1K Views

article

7.3 : 굽힘 및 비틀림 모멘트

Internal Forces

3.5K Views

article

7.4 : 구조부재의 내부 하중: 문제 해결

Internal Forces

1.2K Views

article

7.5 : 빔

Internal Forces

1.3K Views

article

7.6 : 전단 다이어그램

Internal Forces

740 Views

article

7.7 : 굽힘 모멘트 다이어그램

Internal Forces

995 Views

article

7.8 : 분산 하중과 전단의 관계

Internal Forces

603 Views

article

7.10 : Shear and Bending Moment Diagram: 문제 해결

Internal Forces

1.3K Views

article

7.11 : 집중 하중을 받는 케이블

Internal Forces

796 Views

article

7.12 : 분산 부하가 가해지는 케이블

Internal Forces

640 Views

article

7.13 : 자체 무게에 영향을 받는 케이블

Internal Forces

426 Views

article

7.14 : 케이블: 문제 해결

Internal Forces

313 Views

Copyright © 2025 MyJoVE Corporation. 판권 소유