Heat Distribution in Rectangular Fins Using Efficient Finite Element and Differential Quadrature Methods

doi:10.4236/eng.2009.13018

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Engineering, 2009, 1, 151-160

doi:10.4236/eng.2009.13018 Published Online November 2009 (http://www.scirp.org/journal/eng).

Heat Distribution in Rectangular Fins Using Efficient

Finite Element and Differential Quadrature Methods

ShahNor BASRI, M. M. FAKIR, F. MUSTAPHA, D. L. A. MAJID, A. A. JAAFAR

Department of Aerospace Engineering, University Putra Malaysia, Putra, Malaysia

E-mail: shahnor@eng.upm.edu

Received September 2, 2009; revised September 24, 2009; accepted September 28, 2009

Abstract

Finite element method (FEM) and differential quadrature method (DQM) are among important numerical

techniques used in engineering analyses. Usually elements are sub-divided uniformly in FEM (conventional

FEM, CFEM) to obtain temperature distribution behavior in a fin or plate. Hence, extra computational com-

plexity is needed to obtain a fair solution with required accuracy. In this paper, non-uniform sub-elements

are considered for FEM (efficient FEM, EFEM) solution to reduce the computational complexity. Then this

EFEM is applied for the solution of one-dimensional heat transfer problem in a rectangular thin fin. The ob-

tained results are compared with CFEM and efficient DQM (EDQM), with non-uniform mesh generation). It

is found that the EFEM exhibit more accurate results than CFEM and EDQM showing its potentiality.

Keywords: Efficient Finite Element Method, Efficient Differential Quadrature Method, Heat Transfer Problem

1. Introduction

Presently there are many numerical solution techniques

known to the computational mechanics community. FEM

is one of those numerical solution techniques to solve

structural, mechanical, heat transfer, and fluid dynamics

which arise in problems of engineering and physical sci-

ences [1–5]. Here, conventional FEM (CFEM) means the

used elements are of same size and uniformly distributed.

In its application to the solution of engineering problems,

the finite element discretization has been implemented

almost to the spatial problems. For dynamic or time de-

pendent problems whose solutions as functions of time

are of interest, a step by step procedure of finite differ-

ence is usually employed with computational complexity.

For heat transfer problems, rapid changes of

heat/temperature distributions take place near the ele-

ment boundary (and at the boundary). It is very impor-

tant to know these temperature change behavior of an

element prior to its use. Hence, to get an actual picture

using FEM, the element is usually subdivided into very

small sub-elements uniformly (conventional FEM,

CFEM), which leads to huge amount of complexity,

memory consumption and computational time [6]. Oth-

erwise, error flow occurs with unreliable results [1,2,6].

On the other hand, to get a clear picture about the tem-

perature changes near (and at) the element boundary,

better to subdivide the elements into very small sub-

elements at the boundary only, followed by relatively

bigger elements gradually towards the mid-point of the

element non-uniformly (efficient FEM, EFEM). This

may serve the intended purpose without any additional

burden and this is highlighted in this paper with im-

proved accuracy (approximately 65%) compared to

CFEM. Hence, here, focus is given to develop and apply

efficient (non-uniform mesh density) nodal points distri-

bution algorithm for automatic mesh (elements) genera-

tion to optimize CFEM solution.

DQM is another numerical solution technique to solve

above mentioned problems efficiently [7–13]. The es-

sence of the DQM is that the partial derivative of a func-

tion is approximated by a weighted linear sum of the

function values at given discrete points. Bellman and

Casti [7,8] developed this numerical solution technique

in the early 1970s and since then, the technique has been

successfully employed in a variety of problems in engi-

neering and physical sciences. To make the DQM more

efficient with less computational complexity, efficient

DQM (EDQM) was proposed in [11–13] with non-uni-

formly distributed mesh points.

Hence, in this paper, one-dimensional (1-D) heat con-

duction problems in a thin rectangular fin are solved us-

ing EFEM by means of the accurate discretization and

solver (code) and then the results are compared with

S. N. BASRI ET AL.

152

CFEM and EDQM to verify EFEM efficiency.

The paper is organized as follows. Section II presents

the governing equation with efficient FEM rules, fol-

lowed by simulation set-up and assumptions, results and

discussions, and finally conclusion of the paper.

2. The One-Dimensional Efficient Finite

Element Method

Here, the considered one dimensional (1-D) heat conduc-

tion problem is [2,3,14–18]

ddT

dx dx







 (1)

with the boundary conditions 0

0TT x

 and

(

qhTT



) as shown in Figure 1. Here, heat flux

 . Figure 1 shows the 1-D element discretiza-

tion in the x-direction. The temperature

at various

nodal points are the unknowns except at node 1, where,

with initial temperature. Within a typical

element ‘

01 TT 0

x

12e

lx

’ the local node numbers are iand

with coordinates and and element length,

. For example, whose local node num-

bers are 1.and 2 with coordinates and , and ele-

ment length respectively.

1i

1eii





1i



An one-dimensional thin rectangular fin as shown in

Figure 2 is considered here. Heat is transmitted along its

length by conduction and dissipated from its lateral sur-

faces to the surroundings by convection. The governing

equation for the temperature in the fin is given in Equa-

tion (1).

The parameter,

is given by2

MkA

, where, p is

the fin perimeter (meter) and Ac is the cross sectional

area of the fin [meter2]. Fin length, width and thickness

are , and t respectively. Lw

In this case,



qhTT k



 ,





2pwt,

wt and



wt t





. The convection

heat loss in the fin is equivalent to negative heat source

and can be expressed as follows:

 

()

pdxh TTph

Adx A





 T

Now Equation (1) becomes



ddTph

kTT

dx dxA







 (2)

Figure 1. Boundary conditions for 1-D heat conduction.

Figure 2. Thin rectangular fin.

To calculate the approximate solution T, the mathe-

matical formulation using Galerkin’s approach [2,3] is



ddTph

kTTdx

dxdx A

























(3)

where



is a test function constructed from the same

basis functions as those of T, with .







Integrating by parts Equation (3) becomes,



000

LLL

dTd dTph

kkdx TTdx

dxdx dxA











 

(4)

The 1st term of Equation (4) is,

   

00 0

dT dTdT

kLkLLk

dx dxdx

 



(5)

Since









and

 

qkL LhTT

dx 

 ,

we get,

 

kLhT





 

Equation (4) becomes

 

ddT ph

LhTTkdxT Tdx

dx dxA









 



(6)

A global virtual temperature vector is defined as

then within each element, th



123

,,,..., T

 





S. N. BASRI ET AL.

153

test function becomes According to Reference [2],e

dx BT , we have





B

() ii



 (7)

Here, is the element shape function and



the element boundary [2] (Figure 1). Therefore Equation

(7) gives For matrix multiplication validity, we have



TT ei

ddT

dx dx









 T

BψBT













(8)



and



11 1

111

11 11

111

() ()

ii iiiiei

xx xxxxl

 

11







 









 





BB 

The element conductivity matrix is The element heat rate vector due to the heat source is

ei eiei

TTT

kl k















T

BB 



(9)

eieiei ei

Ql Ql







 



T

Rr N (10)

where,



varies from to

11



and

()1

Now, Equation (2) can be transformed into

xwith ddx



 







ei eiei ei

lL TT

ei ei

kl Ql

hT Tdd









 









ψBB TψN







(11)

TLL L

hT hT







ψKT ψR (12)

where, global matrices KT , R, and T are respec-

tively,

1112 13 1

2122 23 2

3132 33 3

122

...

2....................................................

...

ei ei

TTT L

LLLL

KKKK

kl dKK K K

KKKK

















T

KBB

212223221 0

31323333331 0

41424344441 0

123 10

...

....................................... .

...

LL LLLL

KK KKT

KKKT RKT

TRhT

KKK hKT



















 











































(16)





(13)

This equation needs to be solved to obtain the 1-D

FEM numerical temperature distribution in the consid-

ered rectangular fin.



123

...

ei ei

Ql dRRRR







T





(14)

Using Equations (11-16) and the efficient FEM

(EFEM) algorithm, the approximate solution T has been

obtained. The 1-D EFEM algorithm (rule) is depicted in

terms of self-explanatory flow chart in Figure 3. The

non-uniform and uniform mesh distribution scenarios are

shown in Figures 4 and 5 respectively.

000...00 000...00

00...00

010... 00

00...00001... 00

................... ............. ................ ....

................. ............ ................. ......

000... 01

000...0









































2.1. Example Problem 1: 1-D Insulated Tip Thin

Rectangular Fin

(15)

and with constant.



123

... L

TTT TT

T10

TT When the base of the fin is held at constant temperature,

T0 and the tip of the fin is insulated, the boundary condi-

tions are then given by

Finally, the global matrix is formed and the Equation

(12) becomes

S. N. BASRI ET AL.

154

Start and Initialization

Input: Fin Length: L, no. of element:

N, error threshold: eh

Figure 3. Efficient discretization and solution rule for 1-D FEM

No Yes

No No

Yes

No. nodal point:

Z=N+1

Calculation of mesh

distribution

i = 1 to Z

()1 cos

xi Z

















Element length.

i = 1 to N

le(i) = x(i+1) – x(i)

Non-uniform ?

No nodal points:

Z=N+1.Element

len

th: le = L

Mesh distribution calcula-

tion

i = 1 to z,

x(i) = (i – 1)



Numerical solution and

error calculation

Max.

|Tn – Texact|

≤eh?

Set N=N+2

Discretization and Stiff-

ness matrix

calculation using

Galerkin approach

Set N=N+2

END

S. N. BASRI ET AL. 155

TT at 0x

0q at

L, where L is the length of the fin.

In this case, the final form of the global matrix in

Equation (16) becomes

2223221 0

323333331 0

23 1

...

......... ............

...

LL LLLLL

= L

= 0

x = L x = 0

AAA

TR T

AATRAT

AATRA





 



 



 





 



 



 

















(17)

Example of non-uniform and uniform mesh distribu-

tions and element lengths are depicted in Figures 4 and 5

respectively.

2.2. Example Problem 2: 1-D Convection Tip Thin

Rectangular Fin

When the base of the fin is held at a constant temperature,

T0 and the tip of the fin is a convection surface, then the

boundary conditions are T=T0 at x=0



qhT T



 at x=L

And the final global matrix shown in Equation (16)

becomes

2223221 0

323333331 0

23 1

...

......... ............

...

LL LLLLL

AA AAT

AAA TRAT

AA AhTRhTAT

































(18)

3. Simulation Set-up and Assumptions

Table 1 shows the considered parameters and their cor-

responding values used to obtain simulation results using

FORTRAN 90 software. We used these values to obtain

the temperature distribution for EFEM, CFEM, EDQM

and exact methods.

Figure 4: Example 1-D efficient mesh distribution and ele-

ment lengths.

Figure 5. Example 1-D conventional mesh distribution and

element lengths.

We considered, 21

MkA



 and the associated assump-

tions (in Table 1) to compare the obtained FEM results

with DQM [13] and exact solution [18]. Here to mention

that, to obtain 1-D DQM solutions, element material

properties, fin-width and fin-thickness are not required

(which is the shortcoming of the method). The errors in

FEM and DQM solutions are computed compared to

exact solution [18].

4. Results and Discussions

4.1. Results and Discussions of 1-D Insulated Tip

Thin Rectangular Fin

The results of the present problem, shown in Figure 6,

contain the maximum absolute percentage errors in the

FEM and DQM solutions obtained with uniformly (con-

ventional) and non-uniformly (efficient) distributed no-

dal (mesh) points. It is essential to know, how many

mesh points (elements) are required to obtain a conver-

gent FEM solution in the solution domain.

Hence, the comparison of convergence of fin-tem-

perature in terms of maximum % error versus number of

nodal (mesh) points for CFEM, EFEM and EDQM solu-

tions is shown in Figure 6. Initially, all the solutions in

terms of maximum % errors show a monotonic conver-

gence with the increasing number of mesh points (shown

11to 104Z



). It is apparent that EFEM results show

bit less accuracy for 30Z



and similar accuracy for

compared to EDQM, but yields result with higher

accuracy, of one order of magnitude or more with in-

creasing

30Z

compared to CFEM. EDQM converge up to

100Z



and then saturated, whereas the EFEM solutions

converge smoothly for all N within the solution domain,

showing best converging result at . On

the other hand, uniform FEM (CFEM) results converge

slowly throughout the solution domain and then diverge

without showing the best results like EFEM. It happens

due to the mesh point distribution strategy of equally

spaced and unequally spaced nodal points in the compu-

tational domain and the inherited complexity to compute

the stiffness matrix for equally spaced nodal points.

Hence, the efficiency of EFEM results is apparent.

100and 101Z

Figure 7 shows the convergent numerical and exact

solutions (fin temperature) and the corresponding per-

centage errors for 100N



elements (FEM case) which

is equivalent to 101Z



mesh points (both FEM and

DQM cases). These results are obtained at an interval of

0.1x



along the fin length,01

, using cubic

S. N. BASRI ET AL.

156

Table 1. Input parameters and assumptions for 1-d rectangular fin.

spline interpolation. It is seen that all the solutions are

very close to exact solutions throughout the length of the

fin with temperature variations at

01TC0



0.648

TC1.0

m.

Figure 8 shows the percentage errors at the base of the

fin () are 0 for all solutions due to initial tempera-

ture (Figure 7). The percentages errors remain

the same with EFEM except little bit increase (with

maximum error) at the middle of the fin due

to nodal point distribution with maximum spacing there.

Whereas, with CFEM, it increases gradually along the

length of the fin with the maximum percentage error

at the fin-tip (x = 1). In other case, the oscilla-

tions (instability) of DQM results appear clearly com-

pared to FEM results. The average percentage error in

0x

01T

10 



2.44 10



1.9

CFEM, EDQM [13] and EFEM are4

1.2 10



,

and respectively, which shows

approximately 99% and 49% improvements in EFEM

results demonstrating its superiority over CFEM and

EDQM.

2.24 10

6

1.12 10



4.2. Results and Discussion of 1-D Convection Tip

Thin Rectangular Fin

Here the results exhibit the same nature like insulated-tip

fin but yield results with higher accuracy, of two order of

magnitude or more with increasing

due to different

material properties and fin-thickness (as the FEM solu-

tion and its accuracy depend on fin dimension, materials

used and associated boundary conditions).

In Figure 9, the comparison of convergence versus

number of mesh points of exact, FEM and DQM solu-

tions for convection-tip fin with uniform and non-uni-

form mesh distributions is shown. It is apparent that for

all cases, the solutions converge smoothly for all

within the solution domain. The comparison shows

similar results as in Figure 6 except EFEM yields result

with higher accuracy, of one order of magnitude or more

with increasing

(for ) compared to that with

CFEM. Here, EFEM results converge from

20Z

80Z



showing best result at90to 101Z



, EDQM [13] shows

similar results with some oscillations, whereas CFEM

does not exhibit any best convergence.

Input Parameters Assumed value for Insulated-Tip

Fin

Assumed value for Convec-

tion-Tip Fin

Boundary and other values:

Initial temperature (T0)

Ambient temperature (T∞)

Heat flux (q)

% Error threshold (eh)

1 OC

0 OC

0 at x = 1

0 - 0.1

1 OC

0 OC

Variable

0 - 0.1

Element Type (NNODE):

Linear (for 1-D)

Element material properties:

Thermal conductivity (ke = k)

Convective heat transfer coefficient (h)

Heat source (Q)

Variable to make M = 1

9 W/m2 0C

0 W/m3 0C

7.03125 W/(m 0C)

9 W/m2 0C

0 W/m3 0C

Element (Fin) dimension:

length (L) along x-axis

width (w)

thickness (t)

Number of elements (N)

1 m

Variable to make M = 1

0.001 m

11 - 104

1 m

Variable to make M = 1

11 - 104

S. N. BASRI ET AL. 157

Figure 6. Comparison of convergence of insulated-tip fin-temperature in terms of maximum % error for CFEM, EFEM and

EDQM solutions (). 11to 104Z

Figure 7. Insulated-tip fin-temperature distribution for exact, EFEM, CFEM and EDQM along with its respective % errors

(). Z=101

Figure 10 depict the comparison of CFEM, EFEM,

EDQM [13] numerical and exact convection-tip fin tem-

peratures and the corresponding percentage errors for

conventional (uniform) and efficient (non-uniform) mesh

point distribution respectively for 100 elements (i.e.,

). Same as Insulated-tip fin, the results are ob-

tained at an interval of  along the fin length,

101Z

0.1x

, using cubic spline interpolation. Figure 10

shows that, all numerical solutions are very close to ex-

act solutions throughout the length of the fin with tem-

perature variations 0at base of the fin to

at the tip of the fin. Here the reduction of

fin temperature is more compared to insu-

lated-tip fin (Figure 7) as expected.

1T

0.32 C

0.328

T

FEM versus DQM maximum % error comparison for

convection-tip fin-temperature are shown in Figure 11.

The comparison of CFEM, EFEM and EDQM [13] per-

S. N. BASRI ET AL.

158

Figure 8. Percentage error comparison of EFEM, EDQM and CFEM for along the fin-length. Z=101

Figure 9. Comparison of convergence of convection-tip fin-temperature in terms of maximum % error for CFEM, EFEM

and EDQM solutions ().

Z=11to 104

centage errors for convection-tip fin is shown in Figure

11. There is no error at the base of the fin and it almost

remain the same with EFEM and EDQM except negligi-

ble increase at the middle of the fin, whereas, with

CFEM, it increases gradually along the length of the fin

with the maximum percentage error at the tip

(x = 1). In this case the EDQM converges with oscilla-

tions throughout the solution domain. The average %

error in CFEM, EDQM [13] and EFEM are

3.31 10



1.69 6



,

and respectively. This shows

nearly 100% and 99% improvements in EFEM results

3.08 10

11

2.24 10



compared to CFEM and EDQM respectively demonstrat-

ing its superiority.

5. Conclusions

Here, the solutions of the temperature distribution in in-

sulated-tip and convection-tip 1-D rectangular fin are

computed numerically using FEM and the results are

found to agree very well with the exact solution and

show the efficiency of the method. Investigating the

various mesh points distribution for equal and unequal

spacing, it is found that, for FEM solution, unequally

spaced mesh points distribution give better and more

S. N. BASRI ET AL. 159

Figure 10. Convection-tip fin-temperature distribution for exact, EFEM, CFEM and EDQM along with its respective % er-

rors (Z). =101

Figure 11. Convection-tip fin error comparison of EFEM, EDQM and CFEM for along the fin-length. Z=101

accurate results than equally spaced and the solution

converges smoothly as the number of nodal points (or

elements) is increased. In general, this study has im-

proved the stability and accuracy of EFEM results for

practical consideration and implementation.

Finally, the results of EFEM shows remarkable en-

hancement compared to CFEM and agree very well with

EDQM with very small errors or difference showing its

potentiality. Hence EFEM is suitable to test the tem-

perature distribution scenario in any thin metal fin prior

to its design and practical implementation.

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