4.44) Find the Eigen values and Eigen vectors of the matrix

]

4.44) Find the Eigen values and Eigen vectors of the matrix.

[

]

4.45) Use iterative procedures to determine the first and third Eigen values for the structure shown in figure. Hence determine the second Eigen value and the natural frequencies of building. Finally, establish the Eigen vectors and check the rest by applying the orthogonality properties of Eigen vectors. [AU, May / June – 2013]

.

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 72

UNIT – V – APPLICATIONS IN HEAT TRANSFER & FLUID MECHANICS

PART – A

5.1) Write down the one dimensional heat conduction equation. [AU, April / May – 2011]

5.2) Write down the expression of shape function and temperature function for one dimensional heat conduction. [AU, May / June – 2011]

5.3) Write down the governing differential equation for the steady state one dimensional conduction heat transfer.\ [AU, Nov / Dec – 2010, 2012]

5.4) Write down the governing differential equation for a two dimensional steady-state

heat transfer problem. [AU, Nov / Dec – 2009]

5.5) Write down the stiffness matrix equation for one dimensional heat conduction

element. [AU, Nov / Dec – 2011]

5.6) Sketch a two dimensional differential control element for heat transfer and obtain the

heat diffusion equation. [AU, Nov / Dec – 2012]

5.7) Define element capacitance matrix for unsteady state heat transfer problems.

[AU, May / June – 2013]

5.8) Name a few boundary conditions involved in any heat transfer analysis.

[AU, April / May – 2010]

5.9) Mention two natural boundary conditions as applied to thermal problems.

[AU, April / May – 2011]

5.10) Consider a wall of a tank containing a hot liquid at a temperature T₀ with an air stream of temperature Tx passed on the outside, maintaining a wall temperature of TL

at the boundary. Specify the boundary conditions. [AU, April / May – 2009]

5.11) Define static condensation. [AU, Nov / Dec – 2010]

5.12) Give the governing equation of torsion problem. [AU, May / June – 2012]

5.13) Write the step by step procedure of solving a torsion problem by finite element

method. [AU, April / May – 2011]

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 73

5.14) Outline the step by step procedure of handling torsion problem using the finite

element method. [AU, May / June – 2012]

5.15) Define streamline. [AU, May / June – 2012]

5.16) Define the stream function for a one-dimensional incompressible flow.

[AU, April / May – 2011]

5.17) List the applications of the potential flow. [AU, Nov / Dec – 2011]

5.18) List the method of describing the motion of fluid. [AU, May / June – 2012]

5.19) State the relation between the velocity of fluid flow and the hydraulic gradient according to Darcy's law, explaining the terms involved. [AU, Nov / Dec – 2012]

5.20) Define the stream function for a two dimensional incompressible flow.

[AU, May / June – 2013]

Part – B

5.21) Write the mathematical formulation for a steady state heat transfer conduction problem and derive the stiffness and force matrices for the same.

[AU, Nov / Dec – 2008]

5.22) Derive a finite element equation for one dimensional heat conduction with free end

convection. [AU, May / June – 2013]

5.23) The temperature at the four corners of a four – noded rectangle are T₁, T₂ T₃ and T₄. Determine the consistent load vector for a 2-D analysis, aimed to determine the thermal stresses. [AU, Nov / Dec – 2007, April / May – 2009]

5.24) Derive the stiffness matrix and load vectors for fluid mechanics in two dimensional

finite element. [AU, May / June – 2012]

5.25) Give the one-dimensional formulation for one-dimensional flow and derive the element stiffness matrix for the flow through a porous medium.

[AU, Nov / Dec – 2012]

5.26) In the finite element analysis of a two dimensional flow using triangular elements, the velocity components u and v are assumed to vary linearly within an element (e) as

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 74

5.27) Develop stiffness coefficients due to torsion for a three dimensional beam element.

[AU, April / May – 2009]

5.28) Explain the potential function formulation of finite element equations for ideal flow

problems. [AU, May / June – 2013]

5.29) Find the temperature at a point P(1,1.5) inside the triangular element shown with the nodal temperatures given as T₁ = 40⁰C, T_J = 34⁰C, and T_K = 46⁰C. Also determine the location of the 42⁰C contour line for the triangular element shown in figure below.

[AU, April / May - 2008]

5.30) Obtain the finite element equations for the following element. The thermal conductivity (k) of the material of the element is 2 W/ mK. The convective heat transfer coefficient (h) is 3 W/m²K. The ambient temperature (T_f) is 25˚ C. The thickness (t) of the material is 1mm. Assume convection along the edge ‘jk’ alone.

[AU, April / May - 2011]

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 75

5.31) Compute the elemental stress vectors for the following element, assuming plane stress conditions. The nodal displacements in ‘mm’ [q] = [0 1 1 0 1 1]^T. The temperature increase in the element is 5˚C. Take E = 200 GPa and µ = 0.3. The thermal coefficient of expansion is 11 * 10^-6 /˚C. The thickness of the material is 1

mm. [AU, April / May - 2011]

5.32) Calculate the element stiffness matrix and the thermal force vector for the axisymmetric triangular element as shown below. The element experiences a 15⁰ C increase in temperature. Take  = 10 x 10^-6 / ⁰C, E = 2 x 10⁵ N/mm² and = 0.25

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 76

5.33) Determine the temperature and heat fluxes at a location (2, 1) in a square plate as shown in figure. Draw the isothermal for 125°C. T1 = 100°C, T2 = 150°C, T3 =

200°C, T₄ = 50°C [AU, Nov / Dec – 2010]

5.34) Consider a brick wall as shown in figure of thickness L = 30cm, K = 0.7 W/m˚C. The inner surface is at 28˚C and the outer surface is exposed to cold air at -15˚C. The heat transfer coefficient associated with the outside surface is h = 40 W/m²˚C. Determine the steady state temperature distribution within the wall and also the heat flux through the wall. Use a two element model. Assume one dimensional flow.

[AU, April / May – 2011]

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 77

5.35) A composite wall consists of three materials as shown in figure. The outer temperature is T₀ = 20˚C. Convection heat transfer takes place on the inner surface of the wall with T_∞ = 800˚C and h = 25W/m²˚C. Determine the temperature distribution

in the wall. [AU, May / June – 2011]

5.36) A composite wall is made of three different materials. The thermal conductivity of the various sections are k₁ = 2 W/cm ˚C, k₂ = 1 W/cm ˚ C, k₃ = 0.2 = W/cm ˚C. The thickness of the wall for the section is 1cm, 5cm and 4cm respectively. Determine the temperature values of nodal points within the wall. Assume the surface area to unity.

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 78

The left edge of the wall is subjected to a temperature of 30˚C and the right side of the

wall is at 10˚C. [AU, Nov / Dec – 2011]

5.37) Figure shows a sandwiched composite wall. Convection heat loss occurs on the left surface and the temperature on the right surface is constant. Considering a unit area and with the parameters given, use three linear elements (one for each layer) and

(i) Determine the temperature distribution through the composite wall and (ii) Calculate the flux on the right surface of the wall. [AU, Nov / Dec – 2012]

5.38) A wall of 0.6m thickness having thermal conductivity of 1.2 W/m-K the wall is to be insulated with a material of thickness 0.06 m having an average thermal conductivity of 0.3 W/m-K. The inner surface temp is 1000˚C and outside of the insulation is exposed to atmospheric air at 30˚C with heat transfer co-efficient of 35 N/m² K.

Calculate the nodal temperature using FEA. [AU, Nov / Dec – 2011]

5.39) A long bar of rectangular cross section having thermal conductivity of 1.5 W/m^˚C is subjected to the boundary condition as shown below. Two opposite sides are maintained at uniform temperature of 180 ⁰C. One side is insulated and the remaining side is subjected to a convection process with T = 85^˚C and h = 50 W/m^2˚C.

Determine the temperature distribution in the bar.

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 79

5.40) The plane wall shown below is 0.5 m thick. The left surface of the wall is maintained at a constant temperature of 200⁰C and the right surface is insulated. The thermal conductivity K = 25 W/M^oC and there is a uniform heat generation inside the wall of Q = 400 W/m³. Determine the temperature distribution through the wall thickness using linear elements.

5.41) Determine three points on the 50^o C contour line for the rectangular element shown in the figure. The nodal values are _i= 42^o C, _j=54^o C, _k= 56^o C and _m= 46^o C.

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 80

5.42) Compute the steady state temperature distribution for the plate shown in the figure below. A constant temperature of T₀ = 150⁰ C is maintained along the edge y = w and all other edges have zero temperature. The thermal conductivities are K_x = K_y = 1.

Assume w = L = 1 and thickness t = 1.

5.43) A steel rod of diameter d = 2 cm, length l =5 cm and thermal conductivity K = 50 W/m˚C is exposed at one end to a constant temperature of 320˚C. The other end is in ambient air of temperature 20˚C with a convection co-efficient of h = 100 W/m²˚C.

Determine the temperature at the midpoint of the rod using FEA.

[AU, Nov / Dec – 2011]

5.44) Determine the temperature distribution in one dimensional rectangular cross-section as shown in Figure. The fin has rectangular cross-section and is 8cm long 4cm wide and 1cm thick. Assume that convection heat loss occurs from the end of the fin. Take h = 3W / cm˚C, h = 0.1 W / cm²˚ C,T _∞ = 20˚C. [AU, April / May – 2011]

5.45) Calculate the temperature distribution in stainless steel fin shown in figure. The region can be discretized into five elements and six nodes. [AU, April / May – 2009]

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 81

5.46) Calculate the element stiffness matrix and thermal force vector for the plane stress element shown in figure below. The element experiences a rise of 10⁰C.

[AU, April / May - 2008]

5.47) Calculate the temperature at the point for a three noded triangular element as shown in figure. The nodal values are T1 = 40˚C, T2 = 34˚C and T3 = 46˚C. Point A is located at (2, 1.5). Assume the temperature is linearly varying in the element. Also determine the location of 42˚C contour line. [AU, May / June – 2011]

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 82

5.48) Determine the element stiffness matrix and the thermal load vector for the plane stress

element shown in figure. The element experiences 20^oC increase in temperature. Take E = 15e6 N/cm²,  = 0.25, t = 0.5 cm and a = 6e - 6/^o C. [AU, April / May - 2010]

5.49) The triangular element shown in figure is subjected to a constant pressure 10 N/mm² along the edge ij. Assume E = 200 Gpa, Poisson’s ratio  = 0.3 and thickness of the element = 2 mm. The coefficient of thermal expansion of the material  = 2 x10^-6/ ^oC and T = 50^o C. Determine the constitutive matrix (stress-strain relationship matrix D) and the nodal force vector for the element. [AU, Nov / Dec - 2009]

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 83

5.50) Compute the element stiffness matrix and vectors for the element shown in figure when the edge 2 – 3 and 3 – 1 experience heat loss. [AU, May / June – 2012]

5.51) Compute the element matrices and vectors for the element shown below, when the edges j_k and i_k experience convection heat loss.

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 84

5.52) Compute element matrices and vectors for the elements shown in figure when the edge kj experiences convection heat loss. [AU, Nov / Dec – 2009]

5.53) Obtain the finite element solution to the torsion problem for a rectangular cross – sections as shown below. Compute the torque required to produce a twist of 1⁰.

5.54) For the smooth pipe of variable cross-section as shown in Figure. Determine the potentials at the junctions, the velocities in each pipe. The potentials at the left end is 10 m and that at the right end is 2m.The permeability coefficient is 1 m/sec.

[AU, April / May – 2011]

FINITE ELEMENT ANALYSIS QUESTION BANK by ASHOK KUMAR.R (AP / Mech) 85

In document Assignment Booklet Me2353 Finite Element Analysis Dec 2013 May 2014 (Page 71-85)