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Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering PDF Download

Representation of Force 

There are two ways of representation of force. The method used depends on the type of problem being solved and the easiest approach to finding a solution.

1. Scalar Notation

2. Vector Notation

Vector Notation Of Forces 

1. Two Dimensional Force Systems (Coplanar Forces) It is also possible to represent the x and y components of a force in terms of Cartesian unit vectors i and j.

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering  Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

where the scalars Fx and Fy are the x and y scalar components of the vector F.

2. Three Dimensional Force Systems(Non-Coplanar Forces)

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical EngineeringSummary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

Unit Vector 

Vectors having unit magnitude and represents only the direction of vectors is called a unit vector. It is usually denoted by n.

A vector V may be expressed mathematically by multiplying its magnitude V by a vector n whose magnitude is one and whose direction coincides with that of V.

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

The unit vectors along the Rectangular Coordinate axis x, y and z are

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

 

PROBLEMS

1. A force vector F = 700i + 1500j is applied to a bolt. Determine the magnitude of force and the angle it forms with the horizontal.

2. A force of 500 N forms angles 600, 450 and 1200 respectively with x, y and z axes. Write the vector form of force.

Position Vector 

A position vector r is defined as a fixed vector which locates a point in space relative to another point. a) Position Vector of P relative to origin

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

b) Position vector of B with respect to A

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering


A. RESULTANT OF NON COPLANAR FORCES -By Vector Notation 

1. Resultant of Non Coplanar Concurrent Forces

In vector notation, the scalar components of the resultant vector can be obtained by adding algebraically the sum of the corresponding scalar components of the force vectors.

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

where

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

 

B. MOMENT AND COUPLE – In Vector Notation 

Moment 

Moment is a vector quantity whose direction is perpendicular to the plane of the body. The right-hand rule is used to establish the sense of direction of moment.
Vector Formulation

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

Varignon’s Theorem

Vector Formulation Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

Couple 

Vector Formulation

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

Couple vectors are free vectors, i.e., the point of application is not significant.

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

 

Note : Cross Product of vectors

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

 

2. Resultant of Non Coplanar Non-Concurrent Forces

PROBLEMS

1. A table exerts the four forces shown on the floor surface. Reduce the force system to a force– couple system at point O. Determine the resultant of the following force and its location

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

2. Replace the two forces acting on the post by a resultant force and couple moment at point O.

Express the results in Cartesian vector form.

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

 

C. EQUILIBRIUM OF NON COPLANAR FORCES – By Vector Notation

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

 

1. Equilibrium of Non-Coplanar Concurrent Forces 

In vector notation, the equation of equilibrium can be summarized as

Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering

The document Summary: Resultant & Equilibrium of Force System (Non - Coplanar) | Engineering Mechanics for Mechanical Engineering is a part of the Mechanical Engineering Course Engineering Mechanics for Mechanical Engineering.
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FAQs on Summary: Resultant & Equilibrium of Force System (Non - Coplanar) - Engineering Mechanics for Mechanical Engineering

1. What is a force system?
Ans. A force system refers to a collection of forces acting on an object or a structure. It can be either coplanar (all forces lie in the same plane) or non-coplanar (forces do not lie in the same plane).
2. How do you determine the resultant of a non-coplanar force system?
Ans. To determine the resultant of a non-coplanar force system, we need to resolve each force into its components along three mutually perpendicular axes (x, y, and z). Then, we add up the components of all the forces in each direction to obtain the resultant components. Finally, we use the magnitude and direction of the resultant components to find the resultant force.
3. What is the difference between resultant and equilibrium of a force system?
Ans. The resultant of a force system represents the single force that has the same effect as all the individual forces combined. On the other hand, equilibrium of a force system occurs when the resultant force and resultant moment are both zero, meaning that the system is balanced and not undergoing any translation or rotation.
4. How can you determine if a non-coplanar force system is in equilibrium?
Ans. To determine if a non-coplanar force system is in equilibrium, we need to check two conditions: (1) the vector sum of all the forces must be zero, and (2) the vector sum of all the moments about any point must be zero. If both conditions are satisfied, then the force system is in equilibrium.
5. What are some real-life applications of analyzing non-coplanar force systems?
Ans. Analyzing non-coplanar force systems is crucial in various engineering fields. Some examples of real-life applications include analyzing the forces acting on a bridge, determining the stability of a spacecraft in space, calculating the forces on an aircraft during flight, and understanding the forces acting on a crane while lifting heavy loads. These analyses help ensure the safety and efficiency of structures and systems in various industries.
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