Determine the steady-state temperature distribution T(x,y, t -> ∞) in a 1m x 1m slab if...

Once the temperature in an object reaches a steady state, the heat equation becomes the Laplace...

Once the temperature in an object reaches a steady state, the heat equation becomes the Laplace equation. Use separation of variables to derive the steady-state solution to the heat equation on the rectangle R = [0, 1] × [0, 1] with the following Dirichlet boundary conditions: u = 0 on the left and right sides; u = f(x) on the bottom; u = g(x) on the top. That is, solve uxx + uyy = 0 subject to u(0, y) =...

Consider the BVP or the steady-state temperature u(x,y,z) in the airspace between two infinite (in the...

Consider the BVP or the steady-state temperature u(x,y,z) in the airspace between two infinite (in the y and z directions) stone walls that are perpendicular to the x-axis, and are 5 centimeters apart from each other (ie the wall surfaces in contact with the air space are 5 cm. apart), with the first (or left) wall located at x=-1 cm. and the second (or right) wall at x= 4 cm, where ux = -10, and u=100, respectively. Temperature is measure...

The steady-state temperature distribution inside a solid object is described by the following expression, where x...

The steady-state temperature distribution inside a solid object is described by the following expression, where x is the spatial co-ordinate: T(x) =2x3- 3x2 + x +10 If the thermal conductivity and thickness of the solid are 10 W.m-1.K-1 and 0.8 m respectively, what will be the form of heat flux expression? At what point within the solid does the heat flux reach a maximum (or minimum)?

A steady-state heat balance for a rod can be represented as d2T/dx2 - 0.15 T =...

A steady-state heat balance for a rod can be represented as d2T/dx2 - 0.15 T = 0 The rod is 2 m long and the boundary conditions are given as T(0)=240 and T(2)=150. Utilize the shooting method (with simple Euler and an h value of 1) to start with a reasonable guess for T’(0) and then check the proximity of the guess using given information. Explain the reasoning for selecting a new guess, but do not actually perform calculations for...

The temperature T of a flat sheet, at the point (?x, y) ?, is given by...

The temperature T of a flat sheet, at the point (?x, y) ?, is given by T (?x, y) ? ? x ^ 3 - 2xy + ? 2y ^ 22. a) Determine the rate of change of temperature in the direction of the vector v = (?2, −1) ?, from the point P (? − 1,2) ?. b) Calculate the highest rate of temperature growth from P (? − 1,2) ?, as well as the direction in which it...

In each of Problems 1 through 8, find the steady-state solution of the heat conduction equation...

In each of Problems 1 through 8, find the steady-state solution of the heat conduction equation α2uxx = ut that satisfies the given set of boundary conditions. 1. ux (0, t) = 0, u( L, t) = 0 2. u(0, t) = 0, ux ( L, t) = 0

To determine the effect of the temperature dependence of the thermal conductivity on the temperature distribution...

To determine the effect of the temperature dependence of the thermal conductivity on the temperature distribution in a solid, consider a material for which this dependence may be represented by: k = k0 + a T, where “k0“ is a positive constant and “a” is a coefficient that may be positive or negative. Starting with a steady-state energy balance, derive a relationship for temperature (T) as a function of distance (x) from the lower temperature wall. You may assume that...

Determine the steady-state response of the m-s system 2y” + 50y = f(t) where f(t) is...

Determine the steady-state response of the m-s system 2y” + 50y = f(t) where f(t) is given by f(t) = 4 for 0<t<2π, 4π<t<6π, 8π<t<10π, … etc f(t) = 0 for 2π<t<4π, …etc

Solve the heat equation and find the steady state solution : uxx=ut 0<x<1, t>0, u(0,t)=T1, u(1,t)=T2,...

Solve the heat equation and find the steady state solution : uxx=ut 0<x<1, t>0, u(0,t)=T1, u(1,t)=T2, where T1 and T2 are distinct constants, and u(x,0)=0

Solve the heat equation and find the steady state solution: uxx = ut, 0 < x...

Solve the heat equation and find the steady state solution: uxx = ut, 0 < x < 1, t > 0, u(0,t) = T1, u(1,t) = T2, where T1 and T2 are distinct constants, and u(x,0) = 0