Electrical energy storage systems

Rufer A. EPFL. Electrical energy storage system with at least two energy sources having different... 

In a nonexhaustive way, this chapter shows that Li-ion batteries and supercapacitors are very important electrical energy storage systems, where the carbon material plays a central role in the performance. Lately, many types of carbons have been investigated more or less empirically in these cells. However, the works performed recently pay a special attention to find correlations with specific parameters of nanostructured carbons, which is rather difficult because of the highly disordered state of these materials. 

A more detailed description of different types of batteries and other electric energy storage systems for electric vehicles can be found in Sect. 5.3, while a description of the main characteristics and properties of fuel cells for automotive application is given here, starting from some basic concepts of electrochemistry and thermodynamic, and focusing the attention on the operative parameters to be regulated to obtain the best performance in the specific application. 

The main issues of hybrid propulsion systems are discussed in this chapter, drawing attention to basic characteristics of power train components and aspects of energy management within each hybrid configuration. The main characteristics of electric drives are described in Sect. 5.2, different types of electric energy storage systems are analyzed in Sect. 5.3 and Sect. 5.4, while different configurations of hybrid electric vehicles are discussed in Sect. 5.5, with particular reference to fuel cell propulsion systems (Sect. 5.5.4). 

Even with the current technology the lithium polymer batteries represent the state of the art in the field of electric energy storage systems, since they are characterized by very interesting values of the basic electrochemical parameters, as already reported in Table 1.8 in comparison with other batteries today available. 

In this section, the main characteristics of alternative electrical energy storage systems, such flywheels and super capacitors, are described, as these devices might play an important role in the development of vehicles powered by electric propulsion systems. 

The experimental results discussed in this case study are obtained on a fuel ceU power train installed on a laboratory test bench. It is constituted by a 3.5 kW electric drive connected in hybrid configuration to a 2 kW PEM fuel cell system (FCS) and an electrical energy storage system (lead batteries). The main technical specifications of the FCS are reported in Table 6.1, whereas its scheme is shown in Fig. 6.1 [1, 2]. 

A lead-acid battery pack is used as electrical energy storage system, constituted by 4 units, each one of 12 V and 38 Ah. The choice of using lead-acid batteries is essentially motivated by its low cost and good efficiency [2]. The technical specifications of the battery pack are reported in Table 6.4. 

The general theme of electric vehicles is covered in Chap. 5, with particular reference to hybrid vehicles that adopt both fuel cells and batteries/supercapacitors as power sources. The analysis of possible hybrid configurations is presented together with a review of different types of electric energy storage systems. 

Zakeri B, 8501 S (2015) Electrical energy storage systems A comparative life cycle cost analysis. Renew Sustain Energy Rev 42 569-596. doi 10.1016/j.rser.2014.10.011... 

Vogel I, Mdblus A (1991) On some problems of the zinc— bromine system as an electric energy storage system of higher efficiency—I. Kinetics of the bromine electrode. Electrochim Acta 36 1403-1408. doi 10.1016/0013-4686(91)85326-3... 

FreedomCAR Electrical Energy Storage System Abuse Test Manual for Electric and Hybrid Electric Vehicle Applications... 

Battery management systems (BMSs) are real-time systems controlling many functions vital to the correct and safe operation of the electrical energy storage system in EVs and PHEVs. This includes monitoring of temperatures, voltages and currents, maintenance scheduling, battery performance optimization, failure prediction and/or prevention as well as battery data collection/analysis. 

Figure 35.21 Power and energy density of different electric energy storage systems [4].

Nakayama T, Sera Y, Mitsuda A. The current status of development of advanced battery electric energy storage system in Japan, hr Proceedings of the 24th lECEC, Washington... 

Chen, H., T. N. Cong, W. Yang et al. 2009. Progress in electrical energy storage system a critical review. Progress in Natural Science, 19, 291-312. 

S. Furuta, T. Hirabayashi, K. Satoh, and H. Satoh, Status of the MoonUght Project on Advanced Battery Electric Energy Storage System, Proc. 3d Int. Conf. on Batteries for Utility Energy Storage, Kobe, Japan, 1991, pp. 49-63. 

Doughty, D.H. and Crafts, C.C. (2005) Freedom CAR electrical energy storage system abuse test manual for electric and hybrid electric vehicle applications. 

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