Abstract
Lithium-ion batteries for electric mobility applications consist of battery modules made up of many individual battery cells (Fig. 17.1). The number of battery modules depends on the application. The modules are installed in a lithium-ion battery together with a battery management system, a cooling system, temperature management, and power electronics. Different cell types can be used in battery modules; they include round cells, prismatic hardcase cells, or flat cells such as coffee bag cells or pouch cells (more detailed information available in Chapter 9).
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Bibliography
Haselrieder (2013) Efficient electrode production for lithium-ion batteries
Bauer W, Nötzel D (2011) Rheological properties of electrode pastes for lithium iron phosphate and NMC batteries
Flynn J-C, Marsh C (2012) Development of continuous coating technology for lithium-ion electrodes
Haselrieder (2011) Auslegung und Scale-up des Trocknungsprozesses zur Fertigung von leistungsfähigen Elektroden mit optimierter Struktur und Haftung
Zheng Y, Tian L (2012) Calendering effects on the physical and electrochemical properties of Li[Ni1/3Mn1/3Co1/3]O2 cathode
Scrosati B (2002) Advances in lithium-ion batteries
Spahr M, Goers D, Leone A, Grivei E (2011) Development of carbon conductive additives for advanced lithium ion batteries. J Power Sources 196(7):3404 – 34138.
Sanchez-Gonzalez J, Macias-Garcia A, Alexandre-Franco MF, Gomez-Serrano V (2005) Electrical conductivity of carbon blacks under compression. Carbon 43:741 – 747
Sides CR, Croce F, Young VY, Martin CR, Scrosati B (2005) A high-rate, nanocomposite LiFePO4/Carbon cathode. Electrochem Solid-State Lett 8(9):A484 – A487
Chen J, Wang JZ, Minett AI, Liu Y, Lynam C, Liu H, Wallace GG (2009) Carbon nanotube network modified carbon fibre paper for Li-ion batteries. Energy Environ Sci 2:393 – 396
Zhamu A, Shi J, Chen G, Fang Q, Jang BZ (2012) Graphene-enhanced anode particulates for lithium ion batteries. US 2012/0064409 A1
Buqa H, Holzapfel M, Krummeich F, Veit C, Novak P (2006) Study of styrene butadiene rubber and sodium methyl cellulose as binder for negative electrodes in lithium-ion batteries. J Power Sources 161:617 – 62
Lee J-H, Paik U, Hackley VA, Choi Y-M (2005) Effect of carboxymethyl cellulose on aqueous processing of natural graphite negative electrodes and their electrochemical performance for lithium batteries. J Electrochem Soc 152(9):A1763 – A1769
Sano A, Kurihara M, Ogawa K, Iijima T, Maruyama S (2009) Decreasing the initial irreversible capacity loss of graphite negative electrode by alkali-addition. J Power Sources 192:703 – 707
Lee JH, Lee S, Paik U, Choi Y-M (2005) Aqueous processing of natural graphite particulates for lithium-ion battery anodes and their electrochemical performance. J Power Sources 147:249 – 255
Zaidi W, Oumellal Y, Bonnet J-P, Zhang J, Cuevas F, Latroche M, Bobet JL, Aymard L (2011) Carboxymethylcellulose and carboxymethycellulose-formate as binders in MgH2-carbon composites for lithium-ion batteries. J Power sources 196:2854 – 2857
Ouatani LE, Dedryvère R, Ledeuil J-B, Biensan P, Desbrieres J, Gonbeau D (2009) Surface film formation on carbonaceous electrode: influence of the binder chemistry. J Power Sources 89:72 – 80
Lee J-H, Kim H-H, Wee SB, Paik U (2009) Effect of additives on the dispersion properties of aqueous based C/LiFePO4 paste and its impact on lithium ion battery high power properties. Hosaka powder technology foundation, KONA powder and particle. Journal 27
Lanciotti C (2009) Lithium battery cell manufacturing process. Joint European Commission/EPoSS/ERTRAC workshop 2009, Brussels, Kemet Arcotronics Technologies, Sasso Marconi, Italy
Schelisch J (2011) Forschung für die Produktion von Morgen, Portraits der ausgewählten Projekte im BMBF-Programm Forschung für die Produktion von morgen. Projektträger Karlsruhe (PTKA-PFT), Bundesministerium für Bildung und Forschung
Freedom CAR: Electrical energy storage system abuse test manual for electric and hybrid vehicle applications; Sandia Report, SAND 2005 – 3123
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Pettinger, KH., Kampker, A., Hohenthanner, CR., Deutskens, C., Heimes, H., vom Hemdt, A. (2018). Lithium-ion cell and battery production processes. In: Korthauer, R. (eds) Lithium-Ion Batteries: Basics and Applications. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-662-53071-9_17
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