cooling system design for cpv module (concentrate
TRANSCRIPT
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
1/21
Under the guidance of
Mr. Rohini kumar B
Presented By
Kakada naveenkumar
M140527ME
COOLING SYSTEM DESIGN O! CP" P#NEL
$CONCENT!#TE P%OTO"OLT#IC CELL&
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
2/21
• Introduction
• Objective
•
oo!in" #$#tem• Microchanne!#
• %iterature revei&
• Re'erence#
CONTENTS
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
3/21
• () ce!!#*
+ 'hoto(o)taic ce)) i# a #,ecia!i-ed #emiconductor
diode that convert# vi#ib!e !i"ht into direct current /.
• !a##i'ication o' () ce!!#*
1. %o& oncentration () %() 1 to 40 #un#
2. Medium oncentration () M() 40 to 00 #un#. 3i"h oncentration () 3() 00 to 2000 #un#.
Introduction
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
4/21
ontinued...
• India# !ar"e#t ,hotovo!taic () ,o&er ,!ant# *
• 1. Re!iance (o&er (okhran 6o!ar () (!ant Raja#than 40M8.
• 2. +daniBitta 6o!ar (!ant 9ujarat 40M8.
• . Mo#er Baer (atan 9ujarat 0M8.• 4. +-ure (o&er 6abarkantha 9ujarat 10M8.
• 5. 9reen In'ra 6o!ar Ener"$ %imited Rajkot 9ujarat 10
M8.
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
5/21
ontinued...
() conver#ion !o##e# o' a ,o&er ,!ant a# a $ear!$ avera"e
1. !i"ht re'!ection !o##e# .1:
2. !o& radiation and #hado&in" !o##e# .2:. / board !o##e# 1.2:
4. /;+ conver#ion !o##e# 4:
5. tem,erature !o##e# 7.
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
6/21
ontinued...
• =he major 'raction o' !o##e# i# re!ated to the tem,erature
increa#e o' the #i!icon #o!ar ce!!#.
•
(ro,er coo!in" #$#tem i# nece##ar$ to o,erate the #$#temunder concentrated radiation.
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
7/21
• =o de#i"n a coo!in" #$#tem 'or concentrate ,hotovo!taic ce!!#
inorder to obtain hi"her net out,ut ,o&er o' () ce!!# and
,ro!on" their !i'e time.
• >abrication o' () ,ane! and microchanne!# &ith re?uired
dimen#ion#.
OB*ECTI"E
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
8/21
COOLING SYSTEM
Methods of coo)ing syste+
Passi(e +ethods #cti(e +ethods
• @et im,in"ement
• 3$brid @et im,in"ement
• Microchanne!#...etc
• Aatura! convective heat#ink#
!ike heat ,i,e# 'in#...etc
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
9/21
• hanne!# diameter !ie# in bet&een 0.2mm.
• 3i"h heat tran#'er rate#.
• Re!ative!$ !o& ,re##ure dro,#.
•
%o& 'abrication co#t#.• Ea#e o' 'abrication
MIC!O C%#NNELS
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
10/21
Literature re(ie,
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
11/21
1. (er'ormance o' a #i!icon ,hotovo!taic modu!e under
enhanced i!!umination and #e!ective'i!tration o'
incomin" radiation &ith #imu!taneou# coo!in"* Su-arna Maiti ./ 0aira(i "yas/ Push'ito 01 Ghosh
•. +b#or,tion o' radiation &ith di''erent t$,e# !i?uid# .
•. =em,erature ri#e in ,v modu!e &ith time o' da$.
•. maimum ,o&er ,roduced in ,v ce!! &ith the time o' da$.
•. =he #tead$ #tate heat remova! e''icienc$ o' the !i?uid
can be "iven a#*
•.=he maimum ,o&er o' the ,v modu!e can be ca!cu!ated b$
u#in" re!ation#hi,*
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
12/21
In'rared ab#or,tion #,ectra o' di''erent or"anic and inor"anic !i?uid#
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
13/21
=em,erature ,ro'i!e ver#u# time o' da$ o' at di''erent condition#
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
14/21
maimum ,o&er(ma v# time o' da$ 'or di''erent condition# o'
#o!ar radiation
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
15/21
2. + com,arative #tud$ on u#in" #in"!e and mu!ti header
microchanne!# in a h$brid () ce!! coo!in"*
Masoud !ahi+i / Maso+eh #sadi/ Nooshin 0ara+i/ E-rahi+ 0ari+i⇑
• =he () ce!! ha# e''ective area o' 2
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
16/21
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
17/21
B$ u#in" e,eriment re#u!t# variou# "ra,h# ,!otted*
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
18/21
Sl.no
Author Title Comments
1 Kaijun
Yang,Chuncheg Zuo .
A novel multi-
layer manifoldmicrochannelcooling systemfor concentratingphotovoltaic cells
+n e''ective mu!ti!a$er mani'o!d
microchanne! heat #ink 'or the coo!in" o'() ce!!# ha# been #ucce##'u!!$ 'abricated.
B$ re#u!t# obtained 'rom e,eriment he'ound that hi"her heat tran#'er coe''cient anda !o&er #ur'ace.
The pressure drop of microchannelsis lo.
! "asoud#ahimi ,$%rahim
Karimi,"asomeh Asadi,&eyvand'aleh-e-(heyda
)eat transferaugmentation ina hy%rid
microchannelsolar cell
This paper considers e*perimentalinvestigations on a hy%ridmicrochannel solar cell, hich is
designed as anattractive technology for &' coolingsystems.
An e*cellent cooling performanceas found from e*periments so that
the cell ma*imumpoer as marginally improved
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
19/21
3 JeromeBarrau , JoanRosell,DanielChemisana,LounesTadrist ,M. Iban.
Effect of a hy-rid 2eti+'inge+ent3+icro4channe)coo)ing de(ice on
the 'erfor+anceof dense)y 'ac5edP" ce))s underhighconcentration
A new hybrid etim!in"ement#mi$ro%$hannel$oolin" s$heme ha&e beendes$ribed.
This $hara$teristi$ in&ol&esthat,the a&era"e heat e'$han"e$oe($ient o) mi$ro%$hannel$oolin" s$hemes is sli"htlyhi"her than the one o) thehybrid heat sin*
Kyu)yung/o, Tae)oon
Kim, Yong-(hi0)an,yung-2lChoi,"yung-
ae Kim
3eneralcorrelation of anaturalconvective
heat sin0 ithplate-4nsfor highconcentratingphotovoltaicmodule cooling
2n this paper, they proposed somecorrelations. it is shon that theproposed correlation predicts ellthe e5ects of inclination angle
and 4n spacing on the thermalperformance of the naturalconvective heat sin0 ith plate-4ns.
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
20/21
+ .Rad-iems*a.lu"mann
Ther+a))y affected'ara+eters of thecurrent6(o)tagecharacteristics ofsi)icon 'hotoce))
The inf)uence of te+'erature on the'ara+eters of si)icon 'hotoce))s is'resented1
The te+'erature increase of the ce))
surfaces ,ithin the range fro+ 77 to89 degree centigrade1
It is sho,n that the 'roduct IscUoc degrades a-out 91:; 'er < 0te+'erature increase1
6 /r..(.3aali/.A.Kam%l
e
+na!$#i# o'Rectan"u!arMicrochanne!under >orcedconvection 3eat=ran#'er condition
>rom ana!$#i# it i# ob#erved that a#h$drau!ic diameter o' microchanne!i# major conce,t o' microchanne! heattran#'er &hich i# de,endent on '!o& rateo' &ater in microchanne!.
-
8/15/2019 Cooling System Design for Cpv Module (Concentrate
21/21
#eferences
1. 6ada#hiv K. 6uni! K. )iabhav . /ua! ai# trackin" #$#tem# . International
Journal of Innovation in Engineering Research and Technology vol.2 (2015),
2!"#$!$.
2. (Fre-3i"uera# (. Muno- E. +!monacid 9. )ida! (. 9. 3i"h oncentrator
(hoto)o!taic# e''iciencie#* (re#ent #tatu# and 'oreca#t. Rene%a&le and 'ustaina&le
Energy Revie%s, 15(") (2010), 110#115.. .B. 6obhan 6.). 9arime!!a =ran#,ort in microchanne!# e a critica! revie&+nnu.
Rev. 3eat =ran#'er 1 200 150.
. Kri%us, A., Kaftori, /., "ittelman, 3., )irshfeld, A., 7litsanov, Y., 8/ayan, A. A miniature concentrating photovoltaic and thermalsystem. Energy Conversion and Management, 47(20) (2010),3582-3590.