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Abstract

The packaging of a lithium polymer secondary battery involves a wrapping process of an aluminum/polymer laminate film that uses heat sealing. Heat sealing time and sealing block width are important variables in creating packaging requirements for optimal battery performance and safety. In this study, a heat transfer analysis is performed using finite element method to investigate the temperature distribution of the sealing block over the course of the heat sealing process. Heat sealing time and sealing block width were the variables of interest for the heat transfer simulation in order to identify optimal manufacturing conditions. Through the analysis, we successfully identified a minimum heat sealing time less than 3 s and 1.5 mm width of the sealing block that optimizes both the rate of battery production and lithium polymer battery capacity. To validate the quality of heat sealing properties, visual inspection and restrained packaging tests were performed.

Keywords

Heat transfer laminate film packaging process heat sealing Al pouch lithium polymer battery

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References

Abbrent

Greenbaum

. Recent progress in NMR spectroscopy of polymer electrolytes for lithium batteries. Curr Opin Colloid Interface Sci 2013; 18: 228–244.

Golodnitsky

Secondary batteries – lithium rechargeable systems | Electrolytes: Single lithium ion conducting polymers. In: Garche

(ed). Encyclopedia of Electrochemical Power Sources, Amsterdam: Elsevier, 2009, pp. 112–128.

Lian

Guan

H-y

Wen

. Polyvinyl formal based single-ion conductor membranes as polymer electrolytes for lithium ion batteries. J Memb Sci 2014; 469: 67–72.

Zhang

Tran

. How a gel polymer electrolyte affects performance of lithium/sulfur batteries. Electrochim Acta 2013; 114: 296–302.

Yamashita

Okushita

Mochizuki

. Laminated film and secondary battery comprising the same, US: Dai Nippon Printing Co., Ltd, 2010.

Mihindukulasuriya

Lim

L-T

. Heat sealing of LLDPE films: Heat transfer modeling with liquid presence at film–film interface. J Food Eng 2013; 116: 532–540.

Blasiak

Laski

Takosoglu

. Parametric analysis of heat transfer in non-contacting face seals. Int J Heat Mass Transf 2013; 57: 22–31.

Bouquerel

Duforestel

Baillis

. Heat transfer modeling in vacuum insulation panels containing nanoporous silicas – a review. Energ Build 2012; 54: 320–336.

Heo

Kim

. Enhanced heat transfer by room temperature deposition of AlN film on aluminum for a light emitting diode package. Appl Ther Eng 2013; 50: 799–804.

10.

Weder

Rossi

Crespy

4 – testing heat and mass transfer through membranes and coatings for textiles. In: Smith

(ed). Smart textile coatings and laminates, Sawston, Cambridge: Woodhead Publishing, 2010, pp. 95–122.

11.

Johansson

Lesnic

. A method of fundamental solutions for transient heat conduction in layered materials. Eng Anal Boundary Elem 2009; 33: 1362–1367.

12.

Haji-Sheikh

Beck

Agonater

. Steady-state heat conduction in multilayer bodies. Int J Heat Mass Trans 2003; 46: 2363–2379.

13.

Kelly

RSA

. High barrier metallized laminates for food packaging. J Plastic Film Sheet 1987; 3: 41–47.

14.

Goydan

Carroll

Schwope

. Evaluation of polyester and metallized-polyethylene films for chemical protective clothing applications. J Plastic Film Sheet 1990; 6: 106–116.

15.

Lacroix

Blanc

Pébère

. Simulating the galvanic coupling between S-Al2CuMg phase particles and the matrix of 2024 aerospace aluminium alloy. Corros Sci 2012; 64: 213–221.

16.

Rahman

ABMM

Kumar

Gerson

. Galvanic corrosion of laser weldments of AA6061 aluminium alloy. Corros Sci 2007; 49: 4339–4351.

17.

Ravi Sankar

Das

. Experimental analysis of galvanic corrosion of a thin metal film in a multilayer stack for MEMS application. Mater Sci Semiconduct Process 2013; 16: 449–453.

18.

Shi

Rock

Turk

. Minimizing the effects of galvanic corrosion during chemical mechanical planarization of aluminum in moderately acidic slurry solutions. Mater Chem Phys 2012; 136: 1027–1037.

19.

Sascha B. Coupled finite-element modeling of heat sealing and ultrasonic sealing processes for multilayer packaging films. In: 13th Tappi European place conference, Bregenz, Austria, 30 May–1 June 2011.

20.

Incropera

Frank

David

. Fundamentals of heat and mass transfer, 4th ed. Hoboken, New Jersey: John Wiley & Sons, Inc., 1996.

Numerical and experimental analysis of heat sealing of multi-layered laminate films used in lithium polymer battery packaging

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