EBK NUMERICAL METHODS FOR ENGINEERS
EBK NUMERICAL METHODS FOR ENGINEERS
7th Edition
ISBN: 8220100254147
Author: Chapra
Publisher: MCG
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Chapter 24, Problem 1P

Perform the same computation as Sec. 24.1, but compute the amount of heat required to raise the temperature of 1200 g of the material from 150  to  100 ° C . Use Simpson's rule for your computation, with values of T  at 50 ° C increments.

Expert Solution & Answer
Check Mark
To determine

To calculate: The amount of heat required of 1200 g material by using Simpson’s rule, when temperature is increased from 150°C to 100°C.

Answer to Problem 1P

Solution:

The amount of heat required of 1200 g material by using Simpson’s ruleis 38892 cal.

Explanation of Solution

Given Information:

Write the value of the provided temperatures.

T1=150°C and T2=100°C

Write the value of the provided mass of the material.

m=1200 g

Write the value of the temperature increments.

ΔT=50°C

Formula used:

Write the expression of heat required when temperature is increased.

ΔH=mT1T2c(T)dT ,

And,

ΔT=T2T1

Write the expression of the heat capacity of the material, when temperature is increased.

c(T)=0.132+1.56×104T+2.64×107T2

The formula of the 1/3 Simpson’s rule for the number integration is as follows:

abf(x)dx=h6(f(a)+4f(a+b2)+f(b))

The formula of the 3/8 Simpson’s rule for the number integration is as follows:

abf(x)dx=h8(f(a)+3f(2a+b3)+3f(a+2b3)+f(b))

Here, h=ba

Calculation:

Calculate the value of the of c(T) at different values of T.

For T=150°C,

c(T=150°C)=0.132+1.56×104(150°C)+2.64×107(150°C)2=0.11454 cal/g°C

For T=100°C,

c(T=100°C)=0.132+1.56×104(100°C)+2.64×107(100°C)2=0.11904 cal/g°C

For T=50°C,

c(T=50°C)=0.132+1.56×104(50°C)+2.64×107(50°C)2=0.12486 cal/g°C

For T=0°C,

c(T=0°C)=0.132+1.56×104(0°C)+2.64×107(0°C)2=0.132 cal/g°C

For T=50°C,

c(T=50°C)=0.132+1.56×104(50°C)+2.64×107(50°C)2=0.14046 cal/g°C

For T=100°C,

c(T=100°C)=0.132+1.56×104(100°C)+2.64×107(100°C)2=0.15024 cal/g°C

Construct the table for heat capacity c(T) for different value of T.

T (°C)c(T)(cal/g°C)1500.114541000.11904500.1248600.132500.140461000.15024

Calculate the amount of heat required to increase the temperature of 1200g of material from T1=150°C to T2=100°C.

ΔH=m150100c(T)dT …… (1)

Use the integral in equation (1) by dividing the limits in two parts, that can be written as,

ΔH=m(15050c(T)dT+50100c(T)dT) …… (2)

Consider the integral as follows:

I=15050c(T)dT+50100c(T)dT …… (3)

Consider first part of the integral of I is,

I1=15050c(T)dT

Solve the above integral by using Simpson’s 1/3rd rule.

I1=50(150)6(f(150)+4f(150+(50)2)+f(50))=1006(f(150)+4f(100)+f(50))=1006(0.11454+4(0.11904)+0.12486)=11.926 cal/g

Consider the second part of integral I is,

I2=50100c(T)dT

Solve the above integral by using Simpson’s 3/8th rule.

I2=100(50)8(f(50)+3f(2(50)+1003)+3f(50+2(100)3)+f(100))=1508(f(50)+3f(0)+3f(50)+f(100))=1508(0.12486+3(0.132)+3(0.14046)+0.15024)=20.484 cal/g

Substitute 20.484 cal/g for I2 and 11.926 cal/g for I1 in equation (3).

I=I1+I2=11.926 cal/g+20.484 cal/g=32.41 cal/g

Substitute 32.41 cal/g for I and 1200 g for m in equation (2).

ΔH=mI=(1200 g)(32.41 cal/g)=38892 cal

Therefore, the heat required to increase temperature of the material by using Simpson’s ruleis 38892 cal.

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Chapter 24 Solutions

EBK NUMERICAL METHODS FOR ENGINEERS

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