003 g muthu

Presenting Author
G.Muthu
Research scholar
Department of Mechanical Engineering
National Institute of Technology
Tiruchirappalli
Tamil Nadu
Co Authors
Prof. S.Shanmugam
Prof. AR.Veerappan

1

National Institute of Technology Tiruchirappalli, India

10-Dec-13

Solar Parabolic Dish Thermoelectric
Generator with Acrylic Cover

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10-Dec-13

Outline
 Introduction
 Methodology
 Results
 Discussion
 Conclusions
 References

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10-Dec-13

Introduction
 Concentrating

solar power (CSP) systems namely
parabolic trough, linear Fresnel reflector, power
tower and parabolic dish can be used effectively to
convert solar energy into heat.
 Solar thermal thermoelectric generator is the most
promising option.
 Working principle - Seebeck effect.

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10-Dec-13

Seebeck Effect

5

10-Dec-13

Applications of Thermoelectric power
Cooling fans
 Thermoelectric generators
 Field generators
 Firewood generators
 Bio-fuel generators
 Vehicle exhaust waste heat generators
 Waste incineration generator systems


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10-Dec-13

Structure of Thermoelectric Module

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10-Dec-13

Specification of Module
Model name: TEP1-12656-0.6

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10-Dec-13

Properties of Thermoelectric Module
Ref : Thermonamic Electronics (Xiamen) Co.,Ltd.,China.



Seebeck coefficient (α ) =190~ 200 10-6 V / K



Electrical Resistivity ()= 0.926 10-5 ~ 0.9615 10-5 Ω- m



9

Material : Bismuth Telluride alloy (Bi2 Te3)

Thermal conductivity (K) = 1.2 ~ 1.6 W/mK


10-Dec-13

Model of solar TEG

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10-Dec-13

Specification of parabolic dish concentrator
Open mouth diameter of dish
 Parabolic concentrator surface area
 Height of the parabola
 Reflectivity of the concentrator
 Focal distance


11


3.56 m
10.53 m2
0.7 m
0.78
1.11 m

10-Dec-13

Useful energy gained


12

The useful energy gained (Qu) on the hot side of
TEG


10-Dec-13

Heat loss coefficient


If the wind flows over the receiver plate surface at
Vm m/sec, the heat loss coefficient due to the wind
hw, is given by (McAdams, 1954).
hw=5.7+3.8Vm

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10-Dec-13

Instantaneous thermal efficiency


14

The instantaneous thermal efficiency of the
parabolic dish collector is expressed as


10-Dec-13

Thermoelectric generator equations


The amount of heat removed from cold side (Qc)
and that supplied to hot side (Qh) of the TEG are

Where S=2 N

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10-Dec-13

Properties of Thermoelectric Module
Thermoelectric properties are computed from the
following expression (Melcor, 2009).
2
 (Tavg )  (22224  930.6Tavg  0.9905T avg )  109

 (Tavg )  (5112  163.4Tavg  0.6279T avg )  10
2

10

K (Tavg )  (62605 277.7Tavg  0.4131 avg ) 104
T2

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10-Dec-13

Electric output & TEG Efficiency
The output (Pteg) from TEG is estimated from the
relation

The efficiency of TEG

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10-Dec-13

Overall efficiency


18

Overall system efficiency (ηoverall ) is computed
from the relations


10-Dec-13

Results

Receiver plate temperature with solar beam
radiation
390

Receiver plate temperature (K)

With cover
370

Without cover

350

330

310

290

270

250
500

600

700

800

900

1000

1100

Solar beam radiation (W/m2)

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10-Dec-13

Instantaneous thermal efficiency of parabolic
dish collector (%)

Instantaneous thermal efficiency of collector
with solar beam radiation
68.0

With cover

67.5

Without cover

67.0

66.5

66.0

65.5

65.0

64.5

64.0
500

600

700

800

900

1000

1100


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10-Dec-13

The output voltage for various solar beam
radiations
Output voltage of the system (Volts)

4.5
With cover

4

Without cover

3.5
3
2.5
2
1.5
1
0.5
0
500

600

700

800

900

1000

1100


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10-Dec-13

Output power with solar beam radiation
4

Electrical power output (w)

3.5

3

2.5

2

1.5

1
With cover

0.5
Without cover
0
500

600

700

800

900

1000

1100


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10-Dec-13

Overall efficiency of the System with solar
beam radiation
Overall efficiency of the system (%)

1.8
1.6

With cover

1.4

Without cover

1.2
1
0.8
0.6
0.4
0.2

0
500

600

700

800

900

1000

1100


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10-Dec-13

Conclusions




There is 2.11% improvement in overall efficiency for TEG with
cover as compared to that without cover.



The maximum voltage of the thermoelectric module achieved
was 4 volts, which is 10.75% higher than TEG without cover for
same solar beam radiation.



24

A maximum of 383 K receiver plate temperature was obtained
for TEG with cover at solar beam radiation of 1050 W/m2. It is
1.56% higher than in TEG without cover for the same solar beam
radiation.

The electrical power output for modified TEG was 2.51% higher
than that of the TEG without cover.


10-Dec-13

Photographic view - TEG with solar dish

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10-Dec-13

References
[1] Reddy, K.S. and Sendhil Kumar, N. (2008) Combined
laminar natural convection and surface radiation heat
transfer in a modified cavity receiver of solar parabolic
dish,
International
Journal
of
Thermal
Sciences, 47, pp.1647–1657.
[2] Sukhatme, S.P. and Nayak, J.K. (2012) Solar energy:
principles of thermal collection and storage, Edition
2, Tata McGraw Hill Publishing Company limited, India.
[3]
Shanmugam,
S.,
Eswaramoorthy,
M.,
and
Veerappan, AR. (2011) Mathematical Modeling of
Thermoelectric Generator Driven, Applied Solar
Energy, 47(1), pp31–35.
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10-Dec-13

References
[4] Eswaramoorthy, M. and Shanmugam, S.(2012) Numerical
Model to Compute Heat Loss in Focal Receiver of Solar
Parabolic Dish Thermoelectric Generator, Energy
Sources, Part A: Recovery, Utilization Environmental
Effects, 34, pp 959-965.

[5] Eswaramoorthy, M. (2010) Studies on solar parabolic dish
thermoelectric generator, Ph.D. Thesis, Department of
Mechanical
Engineering,
National
Institute
of
Technology, Tiruchirappalli, India.

27


10-Dec-13

003 g muthu

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