EBK NUMERICAL METHODS FOR ENGINEERS
EBK NUMERICAL METHODS FOR ENGINEERS
7th Edition
ISBN: 8220100254147
Author: Chapra
Publisher: MCG
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Chapter 32, Problem 1P

Perform the same computation as in Sec. 32.1, but use Δ x = 1.25 .

Expert Solution & Answer
Check Mark
To determine

To calculate: The concentration of the distributed-parameter system equations for Δx=1.25. (Refer Sec. 32.1)

Answer to Problem 1P

Solution: The concentration of equations for Δx=1.25 is shown below.

EBK NUMERICAL METHODS FOR ENGINEERS, Chapter 32, Problem 1P , additional homework tip  1

Explanation of Solution

Given Information:

The distributed-parameter system depicts chemical modelling being subjected to first order decay and the tank is mixed well vertically and laterally.

Apply finite length of segment, Δx. So, the equation formed is of the form,

VΔcΔt=Qc(x)Q[ c(x)+c(x)xΔx ]DAcc(x)x+DAc[ c(x)x+xc(x)xΔx ]kVc

Here, V

is the volume, Q

is the flow rate, c

is the concentration, D

is the dispersion coefficient, Ac

is the tank’s cross-sectional area, and k

is the first order decay coefficient.

Calculation:

Qcin=Qc0DAcc0x …… (1)

Substitute centred finite differences for the first and the second derivatives in equation (1) to develop steady-state solution,

Dci+12ci+ci1Δx2Uci+1`ci12Δxkci=0

Further simplify the equation,

(2DUΔx+kΔxU+2+ΔxUD)c0(DUΔx)c1=(2+ΔxUD)cin …… (2)

And,

(DUΔx+12)ci1+(2DUΔx+kΔxU)ci(DUΔx12)ci+1=0 …… (3)

Also,

(DUΔx)cn1+(2DUΔx+kΔxU)cn=0 …… (4)

Solve the equation (2),

(2DUΔx+kΔxU+2+ΔxUD)c0(DUΔx)c1=(2+ΔxUD)cin

Substitute D=2, U=1, cin=100, Δx=1.25, and k=0.2,

(2×21×1.25+0.2×1.251+2+1.25×12)c0(21×1.25)c1=(2+1.25×12)100(3.2+0.25+2+0.625)c0(1.6)c1=(2+0.625)1006.075c01.6c1=262.5

Hence, the required first equation is 6.075c01.6c1=262.5.

Solve the equation (3),

(DUΔx+12)ci1+(2DUΔx+kΔxU)c0(DUΔx12)ci+1=0

Substitute D=2, U=1, cin=100, Δx=1.25, and k=0.2,

(21×1.25+12)ci1+(2×21×1.25+0.2×1.251)c0(21×1.2512)ci+1=0(2.1)ci1+(3.45)c0(1.1)ci+1=0

Hence, the required middle equation is (2.1)ci1+(3.45)c0(1.1)ci+1=0.

Substitute i=1

in middle equation,

(2.1)ci1+(3.45)c0(1.1)ci+1=0(2.1)c11+(3.45)c1(1.1)c1+1=02.1c0+3.45c11.1c2=0

Substitute i=2 in middle equation,

(2.1)ci1+(3.45)ci(1.1)ci+1=0(2.1)c21+(3.45)c2(1.1)c2+1=02.1c1+3.45c21.1c3=0

Substitute i=3 in middle equation,

(2.1)ci1+(3.45)ci(1.1)ci+1=0(2.1)c31+(3.45)c3(1.1)c3+1=02.1c2+3.45c31.1c4=0

Substitute i=4 in middle equation,

(2.1)c41+(3.45)ci(1.1)c4+1=0(2.1)c41+(3.45)c4(1.1)c4+1=02.1c3+3.45c41.1c5=0

Substitute i=5

in middle equation,

(2.1)ci1+(3.45)ci(1.1)ci+1=0(2.1)c51+(3.45)c5(1.1)c5+1=02.1c4+3.45c51.1c6=0

Substitute i=6

in middle equation,

(2.1)ci1+(3.45)ci(1.1)ci+1=0(2.1)c61+(3.45)c6(1.1)c6+1=02.1c5+3.45c61.1c7=0

Substitute i=7

in middle equation,

(2.1)ci1+(3.45)ci(1.1)ci+1=0(2.1)c71+(3.45)c7(1.1)c7+1=02.1c6+3.45c71.1c8=0

Substitute i=8

in middle equation,

(2.1)ci1+(3.45)ci(1.1)ci+1=0(2.1)c81+(3.45)c8(1.1)c8+1=02.1c7+3.45c81.1c9=0

Solve equation (4) for last equation,

(DUΔx)cn1+(2DUΔx+kΔxU)cn=0

Substitute D=2, U=1, cin=100, Δx=1.25, and k=0.2,

(21×1.25)c91+(2×21×1.25+0.2×1.251)c9=01.6c8+3.45c9=0

Hence, the required last equation is 1.6c8+3.45c9=0

Write all the equations in matrix form,

[ 6.075c01.6c12.1c0+3.45c11.1c22.1c1+3.45c21.1c32.1c2+3.45c31.1c42.1c3+3.45c41.1c52.1c4+3.45c51.1c62.1c5+3.45c61.1c72.1c6+3.45c71.1c82.1c7+3.45c81.1c91.6c8+3.45c9]=[ 262.5000000000 ]

Express the matrix in tri-diagonal form,

[ 6.0751.6000000002.13.451.1000000002.13.451.1000000002.13.451.1000000002.13.451.1000000002.13.451.1000000002.13.451.1000000002.13.451.1000000002.13.451.1000000001.63.45 ][ c0c1c2c3c4c5c6c7c8c9 ]=[ 262.5000000000 ]

Use MATLAB to solve the above matrix.

% declare the matrix size

A = zeros(10,10);

% define the values of matrix A

A(1,1) = 6.075;

A(1,2) = -3.2;

A(2,1) = -2.1;

A(2,2) = 3.45;

A(2,3) = -1.1;

A(3,2) = -2.1;

A(3,3) = 3.45;

A(3,4) = -1.1;

A(4,3) = -2.1;

A(4,4) = 3.45;

A(4,5) = -1.1;

A(5,4) = -2.1;

A(5,5) = 3.45;

A(5,6) = -1.1;

A(6,5) = -2.1;

A(6,6) = 3.45;

A(6,7) = -1.1;

A(7,6) = -2.1;

A(7,7) = 3.45;

A(7,8) = -1.1;

A(8,7) = -2.1;

A(8,8) = 3.45;

A(8,9) = -1.1;

A(9,8) = -2.1;

A(9,9) = 3.45;

A(9,10) = -1.1;

A(10,9) = -3.2;

A(10,10) = 3.45;

% define the matrix b

b = [262.5;0;0;0;0;0;0;0;0;0];

% solve the inverse of matrix

Sol = A\b

The output of the program is given below.

EBK NUMERICAL METHODS FOR ENGINEERS, Chapter 32, Problem 1P , additional homework tip  2

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