Finite Element Method in Engineering

Questions and Answers

The principle of Maximum Potential Energy is commonly used in the weak form method based on variational principles.

False

In the Galerkin method of weighted residuals, the solution to the differential equation is approximated using a single assumed trial function.

False

Shape functions in elements of the finite element method are typically non-polynomial functions for better accuracy.

False

Engineers using the finite element method are not responsible for tasks like mesh quality and result interpretation.

False

Software plays a minimal role in finite element analysis as engineers handle most of the tasks manually.

False

The finite element method is an analytical technique used to solve complex engineering problems.

False

In the finite element method, a body is split into small elements connected at nodes, forming a mesh.

True

The main goal of finite element analysis is to calculate stresses and strains within the structure directly.

False

The stiffness matrix of each element defines how nodes deform under applied forces and moments.

True

The global stiffness matrix is formed by subtracting individual element stiffness matrices based on how the elements are connected in the mesh.

False

The stiffness matrix for different element types in the finite element method is derived based on equilibrium concepts.

True

Study Notes

• The finite element method is a numerical technique used in engineering to solve complex problems that cannot be solved analytically.
• It involves splitting a body into small elements connected at nodes, called a mesh, to simplify calculations.
• Different types of elements like surface, solid, and line elements are used based on the geometry and loading conditions of the problem.
• The main goal of finite element analysis is to calculate displacements at nodes, which helps determine stresses and strains within the structure.
• Displacements are calculated using the stiffness matrix of each element, which defines how nodes deform under applied forces and moments.
• The global stiffness matrix is formed by assembling individual element stiffness matrices based on how the elements are connected in the mesh.
• Once the global stiffness matrix is defined, external loads and boundary conditions are applied to solve for nodal displacements using methods like the conjugate gradient method.
• After obtaining displacements, strains and stresses can be calculated throughout the mesh, making it a powerful tool for analyzing structural mechanics problems in various industries.- The stiffness matrix for different element types in the finite element method is derived based on equilibrium concepts.
• Two main methods for deriving stiffness matrices are the direct method and weak form methods (variational principles and Galerkin method).
• The principle of Minimum Potential Energy is commonly used in the weak form method based on variational principles.
• The Galerkin method of weighted residuals approximates the solution to the differential equation by using multiple assumed trial functions.
• Both weak form methods provide approximate solutions to equilibrium equations used in stress analysis problems.
• Elements in the finite element method require shape functions (usually polynomials) to interpolate values within the element.
• The finite element method involves defining the problem, splitting the body into elements, defining element stiffness matrices, assembling global stiffness matrices, solving for displacements, calculating field variables, post-processing, and model validation.
• While software aids in tasks like calculating stiffness matrices, engineers are responsible for proper problem definition, mesh quality, and result interpretation.

Description

Test your knowledge on the finite element method, a powerful numerical technique used in engineering to solve complex structural mechanics problems. Learn about meshing, stiffness matrices, global matrices, nodal displacements, and more.