poster session 2016 eu pvsec: compatibility of pv ribbons and fluxes with eva encapsulant films
TRANSCRIPT
Compatibility of PV Ribbons and Fluxes with EVA Laminating FilmsNarahari S Pujari*, Mike Murphy and Anna Lifton*:[email protected]
�The reliability requirements for module
service life are very high (for 25-30 years of
service life)
� Packaging is the predominant cause of
failure in modules
�Industry often concerns for dis-coloration
and subsequent loss of efficiency of the
module due to the degradation in the
encapsulant properties (yellowing,
greening (corrosion), efficiency losses, etc.
Introduction Experimental
1. Miller Dave, “The Critical Role of Materials in the Solar PV
Industry”, GW Solar Institute Symposium, 2010.
2. S. Jiang et al., “Encapsulation of PV Modules Using Ethylene
Vinyl Acetate Copolymer as the Encapsulant”, Macromolecular
React. Eng. 9, 522, 2015.
3. E. Kaplani, “Degradation in Field -aged Crystalline Silicon
Photovoltaic Modules and Diagnosis using
Electroluminescence Imaging”, 8th International Workshop on
Teaching in Photovoltaics IWTPV, 2016.
4. H. Raj, Polymer Encapsulants for Photovoltaic Applications’
Internal Cookson Electronics Report, 2009.
Acknowledgements: We thank Dr. S. Sarkar for help and support
DOE
Factor 1
Ribbon type
Ribbons from four sources
Lead free, Ecosol
Factor 2
Flux type
Alpha’s PV fluxes
Factor 3
EVA type
Slow curing EVA
Fast curing
EVA
Observation: a. PV ribbon analysis (Visual / Optical observations)
b. Alloy composition and microstructure (surface contamination,
thickness uniformity and edge exposure)
c. EVA compatibility: Gel content, damp heat, optical observation
Results & Discussion
75
80
85
90
95
100
EVA15295 EVA9918
% G
el
Effect of fluxes on EVA gel content
Control
PV-32
PV50
PV21
PV61
Yellowing
� EVA protects the surface of the ribbons especially in presence of front
glass would prevent whole PV assembly from discoloration/corrosion.
� As tinned PV ribbon surface morphology does not lay a significant
role in resistance to yellowing (in case when the same alloy
composition was used and surface cleanliness was acceptable),
various types of EVA itself exhibit different resistance to discoloration
� Flux compatibility depends upon activity level in the formulation.
� Lead-free EcoSol alloy could be laminated at high temperatures. It
shows good compatibility with EVA and excellent solder joints. This
data further supports transitioning to lead free solar modules.
� Scant amount of information available on
compatibility of lead free alloys with EVA
Effect of Ribbons and Lamination Studies
� Tinning process has an effect on
morphology and grain structure
� IMC layers formation is also a function
of tinning process
� Solder thickness seems to be
consistent expect on the edges
� As expected, PV ribbon coated with
various fluxes but not laminated with
EVA appears to be attacked/corroded
while the fluxed material which was
laminated did not show corrosion, just
discolorationEVA A9918 EVA15295
Effect of Flux and EVA Compatibility
Ecosol, lead free ribbon and microstructure
� Lead free alloy shows uniform
microstructrure, has a similar appearance as
alloys currently in use.
� Due to high liquidus temperature (179oC),
Ecosol ribbon could withstand high
laminating temperature (155oC).
� No colorization noted and solder joints
were strong (>3 N/m2).
� Flux or EcoSol does not seem to have any
adverse effect on EVA.
Ecosol and EVA Compatibility
PV-21 PV-38 PV-50 PV-61
EVA doped with different fluxes and cured
ConclusionReferences
Damp heat testing results
0
-5%
Lowest allowable change
Highest allowable change+5%
Voc Isc Pmax FF
0.9
5
0.7
4-0.56
-0.11
0.2
7
0.3
9
0.1
7
0.3
2
0.3
0
0.0
6
0.1
9
0.3
9
0.3
4
0.4
7
0.5
9
1.2
4
1.5
9
0.6
7
1.5
1
0.6
3
0.5
3
0.6
3
1.0
6
-0.34
% c
ha
ng
e a
fte
r co
nd
itio
nin
g
60/40Ecos
ol
SP2