版權(quán)說(shuō)明:本文檔由用戶(hù)提供并上傳,收益歸屬內(nèi)容提供方,若內(nèi)容存在侵權(quán),請(qǐng)進(jìn)行舉報(bào)或認(rèn)領(lǐng)
文檔簡(jiǎn)介
1、 Abstract To develop electrical busses for applications with a fast recharge system in stations, PVI has been testing some electrical energy components like supercapacitors and batteries with high power density.
2、 Neverthless, supercapacitors limit average autonomy between two recharge points, due to their poor energy density. On the other side cycle life of batteries are very dependent on current. To surmount these problem
3、s, PVI in collaboration with the FCLAB laboratory and the AMPERE laboratory, are studying Lithium-ion capacitor (LIC) for applications with fast recharge. We take to assess how the storage system meets busses power
4、and energy requirements in heavy electric vehicles. We note that the advantage of LIC technology compared to conventional supercapacitor lies in the fact that the energy density and the nominal voltage are higher. In
5、this study, the Li-ion capacitor is characterized and modelled. The characterization and modelling methods are the same of supercapacitor with double layer activated carbon technology. The LIC efficiency will be
6、 discussed. I. INTRODUCTION Lithium Ion capacitor is a new storage device which combines high power density and high energy density compared to conventional supercapacitor of the market. It has four time higher energy
7、 density than conventional supercapacitor. The structure of the LIC is composed by two electrodes. The positive one is formed by activated carbon as in double layer capacitor. The negative electrode uses lithium ion
8、doped carbon. This new electrode technology boosts the capacity of the negative electrode and increases the electrical potential difference. The electrolyte is based on the Li Ion. Figure 1 shows the elementary stru
9、cture of EDLC and Li-ion capacitor structure. It can be seen that the negative LIC electrode is formed by Li doped Carbone. The equivalent capacitance is formed by the positive electrode capacitance Cdl in series with
10、 the negative one Cli. The equivalent capacitor can be expressed as following: Cli1Cdl1C1eq + =(1) where Cli >> Cdl ? dl eq C C ≈(2) Fig. 1: Elementary structure of EDLC and Li-ion capacitor (JM Energy [1]) The
11、Li Ion capacitor studied in this paper ( figure 2) is fabricated by JM Energy. Their parameters are: nominal capacitance: 2000F; volume 124ml; weight: 208g, ESSCAP’2008 – Lithium Ion capacitor characterization and mod
12、elling H. Gualous(1), G. Alcicek(1), Y. Diab(3), A. Hammar(2), P. Venet(3), K. Adams(4), M. Akiyama(4), C. Marumo(5) (1) FCLAB-SeT, UTBM-UFC, bat F, rue Thierry Mieg 90010 Belfort, (2) PVI, Rue de maison rouge - Zone i
13、ndustrielle Gretz Armainvilliers France (3) AMPERE UMR CNRS 5005, Université de Lyon, Université Lyon 1, 69622 Villeurbanne Cedex, France (4) JSR Micro NV Leuven, Belgium (5) JM Energy, Japan hamid.gualo
14、us@univ-fcomte.fr ESSCAP’08 – 3rd European Symposium on Supercapacitors and ApplicationsRoma (Italy) November 6-7, 2008hal-00373149, version 1 - 27 Aug 2009Author manuscript, published in “ESSCAP, Rome : Italie (200
15、8)“Fig. 5: Charge and discharge of Li Capacitor at constant current TABLE II. ESR OF 2000F LI-ION CAPACITOR Current (A) ESR (m?) 50 1.84 100 1.70 150 1.78 ESR variations with current for these three values can be
16、neglected. B. AC characterization The Li-ion capacitor AC characterization was realized using an Electrochemical Impedance Spectroscopy (EIS). To characterize the studied device, the sweep in frequency must be done fo
17、r various voltage levels. EIS allows the study of the influence of frequency on the Li Ion capacitor. Figure 6 presents the variation of the negative imaginary part as a function of the real part for different voltag
18、e values. It can be seen that the Li-ion capacitor equivalent capacitance C is not linear with voltage. -0.00200.0020.0040.0060.0080.010 0.0005 0.001 0.0015 0.002 0.0025 0.003 0.0035 0.004Re (Z)Im (Z )IM_3.8VIM_2.2VIM
19、_2.6VIM_3.0VIM_3.4VFig. 6: Li Ion capacitor imaginary part as a function of real part for 2.2V, 2.6V, 3V; 3.4V and 3.8V It assumed as a first approximation that Li-ion capacitor is modelled by a resistance in series w
20、ith capacitance. Using the EIS results we deduced the C evolutions as a function of DC voltage. Figure 7 represents the experimental results. It can be seen that Li- ion capacitor equivalent capacitance decreases with
21、 voltage when V<3V and the capacitance increases. 150017001900210023002500270029002 2.5 3 3.5 4Voltage (V)C (F)C(F)-capa4- 1mHzC(F)-capa4- 10mHzC(F)-Capa9- 10mHzC(F)-Capa3- 10mHzFig. 7: C variations with Li-ion capa
22、citor voltage The dc voltage dependency of ESR is depicted in figure 8. No as the classical double layer capacitor, an increase in voltage leads to decrease the ESR. This means in high voltage, we can obtain best dis
23、charging power. Fig. 8 : ESR v. frequency for different voltages Figure 9 shows the variation of capacitance versus the frequency for different voltage from this figure, it(s clear that the Li-ion capacitor equivalent
24、 capacitance C is not linear with voltage. Fig. 9: Capacitance v. frequency for different voltages III. LI-ON CAPACITOR MODELLING To model the LIC components, we have chosen a “multipenetrability” [2] model presented o
25、n figure 10. It is composed of four elements, inductance L, series resistance and complex parallel pore impedances described by the equation below. In the presented model only Zp1 and Zp2 are considered. The model pa
溫馨提示
- 1. 本站所有資源如無(wú)特殊說(shuō)明,都需要本地電腦安裝OFFICE2007和PDF閱讀器。圖紙軟件為CAD,CAXA,PROE,UG,SolidWorks等.壓縮文件請(qǐng)下載最新的WinRAR軟件解壓。
- 2. 本站的文檔不包含任何第三方提供的附件圖紙等,如果需要附件,請(qǐng)聯(lián)系上傳者。文件的所有權(quán)益歸上傳用戶(hù)所有。
- 3. 本站RAR壓縮包中若帶圖紙,網(wǎng)頁(yè)內(nèi)容里面會(huì)有圖紙預(yù)覽,若沒(méi)有圖紙預(yù)覽就沒(méi)有圖紙。
- 4. 未經(jīng)權(quán)益所有人同意不得將文件中的內(nèi)容挪作商業(yè)或盈利用途。
- 5. 眾賞文庫(kù)僅提供信息存儲(chǔ)空間,僅對(duì)用戶(hù)上傳內(nèi)容的表現(xiàn)方式做保護(hù)處理,對(duì)用戶(hù)上傳分享的文檔內(nèi)容本身不做任何修改或編輯,并不能對(duì)任何下載內(nèi)容負(fù)責(zé)。
- 6. 下載文件中如有侵權(quán)或不適當(dāng)內(nèi)容,請(qǐng)與我們聯(lián)系,我們立即糾正。
- 7. 本站不保證下載資源的準(zhǔn)確性、安全性和完整性, 同時(shí)也不承擔(dān)用戶(hù)因使用這些下載資源對(duì)自己和他人造成任何形式的傷害或損失。
最新文檔
- 鋰離子電容器的表征和建模外文翻譯(英文).pdf
- 鋰離子電容器的表征和建模外文翻譯(英文).pdf
- 鋰離子電容器的表征和建模外文翻譯
- 鋰離子電容器的表征和建模外文翻譯
- 鋰離子電容器的表征和建模外文翻譯(譯文)
- 鋰離子電容器的表征和建模外文翻譯(譯文).doc
- 鋰離子電容器的表征和建模外文翻譯(譯文).doc
- 鋰離子超級(jí)電容器的研究.pdf
- 石墨負(fù)極鋰離子電容器性能的研究.pdf
- 鋰離子混合超級(jí)電容器的材料制備及其研究.pdf
- 電容和電容器教案
- 鋰離子電容器集流體的表面改性技術(shù)研究.pdf
- 基于石墨烯基炭氣凝膠的鋰離子電容器研究.pdf
- 基于納米陣列電極材料的鋰離子超級(jí)電容器研究.pdf
- 外文翻譯--粘接劑對(duì)碳碳水系對(duì)稱(chēng)電容器性能的影響(英文)
- 鋰離子電容器Nb2O5負(fù)極材料研究.pdf
- 第一章 第節(jié)電容器和電容電容器和電容導(dǎo)體的電阻
- 過(guò)渡金屬鉬化物在鋰離子電容器中的研究.pdf
- 鋰離子超級(jí)電容器電極材料的制備及其儲(chǔ)能研究.pdf
- 鋰離子電容器用預(yù)鋰化硬炭負(fù)極的研究.pdf
評(píng)論
0/150
提交評(píng)論