ELSEVIER
Abstract
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Journal of Power Sources 127 (2004) 85-92
Advances in ZEBRA batteries
Cord-H.DustmannMES-DEA S.A .. VIa Laveggio /5. CH 6855 Srabio. Swirzerland
JIIIUIII
PDWER
SDURCIS
www.elsevier.comjlocatejjpowsour
ZEBRA batteries use plain salt and nickel as the raw material for their electrodes in combination with a ceramic electrolyte and a moltensalt. This combination provides a battery system related specific energy of 120 Wh/kg and a specific power of 180 W /kg. With these datathe battery is well designed for ali types of electric vehicles and hybrid electric buses. The ZEBRA battery technology is industrialised inSwitzerland where a new plant has a capacity of 2000 packs a year with expansion prepared for 30,000 packs a year.© 2003 Elsevier B.V. Ali rights reserved.
Keywords: ZEBRA battery; Sodium-nickel-chlonde system; High specifìc energy; Beta-alumina ceramic electrolyte; Electric vehicle; Hybrid electnc bus
l. Introduction
The principle ofthe ZEBRA battery was invented in South
Africa and the first patent was applied in 1978. BETA Re
search and Oevelopment Ltd in England continued the de
velopment and was integrated into the joint venture of AEG
(Iater Oaimler) and Anglo American Corpo IO years later.
The jointly founded company AEG Anglo Batteries GmbH
started the pilot line production ofZEBRA batteries in 1994.
After the merger of Oaimler and Chrysler this joint venture
was terminated and the ZEBRA technology was acquired in
total by MES-OEA who industrialised il. The present pro
duction capacity is 2000 battery packs per year in a build
ing designed for a capacity of 30,000 battery packs per
year.
2, ZEBRA technology
ZEBRA batteries use nickel powder and plain salt for
the electrode material, the electrolyte and separator is
13" -AI203-ceramic which is conductive for Né ions but an
insulator for electrons [l].
This sodium-ion conductivity has a reasonable value of
:::0.2 Q-I cm,-I at 260°C and is temperature-dependent
with a positive gradient [2]. For this reason the oper!ltional
temperature of ZE~RA batteries have been chosen for therange of 270--350°C. Fig. I shows the celi and its basic
reaction. There is no side reaction and therefore the charge
E-mai! address:[email protected] (C.-H. Dustmann).
0378-7753/$ - see fronl matter © 2003 Elsevier B.V. Ali nghts reserved.doi:10.1016/j.jpowsour.2oo3.09.039
and discharge cycIe has 100% charge efficiency, no charge
is lost. This is due to the ceramic electrolyte.
The cathode has a porous structure of nickel (Ni) and
salt (NaCI) which is impregnated with NaAICI4, a 50/50
mixture of NaCI and AlCI). This salt liquefies at 154°C and
in the liquid state it is conductive for sodium-ions. It has
the following functions, which are essenti al for the ZEBRA
battery technology:
I. Sodium-ion conductivity inside the cathode
The ZEBRA cells are produced in the discharged state.
The Iiquid salt NaAICI4 is vacuum-impregnated into the
porous nickel-salt mixture that forms the cathode. It con
ducts the sodium-ions between the 13" -Ah03 ceramicsurface and the reaction zone inside the cathode bulk dur
ing charge and discharge and makes ali cathode material
available for energy storage. It also provides a homoge
nous current distribution in the ceramic electrolyte.2. Low resistive celi failure mode
Ceramic is a brittle material and may have a small
crack or may break. In this case the liquid salt NaAICI4
gets into contact with the liquid sodium (the melting point
of sodium is 90°C) and reacts to salt and aluminium:
NaAICI4 + 3Na -+ 4NaCI + AI
In case of small cracks in the 13"-alumina the salt and
aluminium cIoses the crack. In case of a large crack or
break the aluminium formed by the above reaction shorts
the current path between plus and minus so that the celi
goes to low resistance. By this means long chains of 100
or 200 cells only lose the voltage of one celi (2.58 V)
but can continue to be operated. The ZEBRA battery isceli failure tolerant. It has been established that 5-10%
86 C.-H. Dllstmann/Journal oJ Power Sources /27 (2004) 85-92
l~olTCB 5•• ,r Il details onthe right
UI- Current collector
. Il (+ poi e)Nickelchloride + 2NaCI+ Ni+--NiCI2 + 2Na
'I~~Sodiumaluminiumchloride I I•. Ceramic electrolyte
Na AICI4Liquid electrolyte13"- AI2 03Ceramic electrolyteCapillary gapWick
Na AI CI4Liquid electrolyte13"-AI2 03Ceramic electrolyteCapillary gapWick
Charge
Discharge
O~m.fiI;v.m;g;, R i~ n_.I.;
2NaCI + Ni_NiCI2 + 2NaI I
Sodium
Celi can(- pole)
NiCI2 + 2 Nacharge ••.••.
.•••.•discharge2 NaCI + Ni
100% Ah-efficiency
Typical capacity 32Ah
Operating range
OCV 2.58 at 300°C,
Fig. I. Basic celi reactions.
of celIs may fai! before the battery can no !onger beused. The battery controlIer detects this and adjusts alIoperative parameters.
This same reaction of the liquid salt and liquid sodiumis relevant for the high safety standard of ZEBRA batteries: In case of the mechanica! damage of the ceramicseparator due to a crash of the car the two liquids are reacting in the same way and the salt and aluminium passivates the NiCl2-cathode. The energy re!eased is reducedby about 1/3 compared to the normal discharge reactionof sodium with nicke! ch!oride.
3. Overcharge reactionThe charge capacity of the ZEBRA celI is determined
by the quantity of salt (NaCI) avai!ab!e in the cathode. Incase a celI is fulIy charged and the charge vo!tage continues to be applied to the celI for whatever reasons, the!iquid salt NaAICI4 supplies a sodium re serve folIowingthe reversible reaction:
that the breaking behaviour of the vehicle is fundamentalIy unchanged.
4. Over discharge reactionFrom the very first charge the celI has a surplus
of sodium in the anode compartment so that for anover-discharge tolerance sodium is available to maintaincurrent flow at a lower voltage as indicated in Fig. 2.This reaction is equa! to the celI failure reaction but runswithout a ceramic failure.
2.1. ZEBRA cell design
ZEBRA celIs are produced in the discharged state so that -....J
no metalIic sodium is to be handled. AlI the required sodiumis inserted as salt. Fig. I shows the celI designo
The positive pole is connected to the current colIector,which is a hairpin shaped wire with an inside copper corefor low resistivity and an outside Nickel plating so that alI
2NaAICI4 + Ni - 2Na + 2AICb + NiClzCeli voltage [v]
Fig. 2. Celi reactions at 300 cc. Theoretical specifìc energy: 790 Wh/kg
(normal operation).
2Na+2AICI_~+NiC~H Ni+2NaAk:4Overchurge 2Na+NiCl:! H Ni+2NBCINorma) Operation
3Na+NaAK:4 H 4NaCl+AI
•
Overdischarge IThis overcharge reaction requires a higher voltage thanthe normal charge as illustrated in Fig. 2. This has threepractical very welcome consequences:(a) Any further charge current is stopped automaticalIy
as soon as the increased open circuit voltage equalises
thè charger voltage.(b) If celIs are failed in paralIel strings of celÌ!>in a bat
tery, the remaining celIs in the string with the failedcelIs can be overcharged in order to balance the volt
age of'jthe failed celIs.(c) For a vehicle with' a fulIy charged battery which is
then required to go down hill there is an overchargecapacity of up to 5% for regenerative breaking so
3,05
2.58
l,58
100 o Statos of charge [%]
C.-H. Dustmann/ Journa/ oJ Power SOllrces /27 (2004) 85-92 87
Fig. 3. 13"ceramic with thennaI compression bond (TCB) seal.
Fig. 5. Cooling plates.
material in contact with the cathode is consistent with the
'--' celi chemistry.The cathode material in fonn of a granulated mixture of
salt with nickel powder and traces of iron and aluminium isfilled into the beta-alumina tube (Fig. 3).
This tube is corrugated for resistance reduction by theincreased surface and is surrounded and supported to the celicase by a 0.1 mm thick steel sheet that forms a capillary gapsurrounding the beta-alumina tube. Due to capilIary forcethe sodium is wicked to the top of the beta-tube and wets itindependent of the sodium level in the anode compartment.
The celi case is formed out of a rectangular tube continuously welded and formed from a nickel coated steel strip (seebelow) and a laser welded bottom cap. The celi case fonnsthe negative pole. The celi is hennetically sealed by laserwelded nickel rings that are thermo-compression-bonded(TCB) to an a-alumina collar which is glass brazed to thebeta-alumina tube.
2.2. ZEBRA battery design
ZEBRA cells can be connected in parallel and in series.Different battery types have been made with one to five paralleI strings, up to 220 cells in series and 100-500 cells inone battery pack. The standard battery type Z5 (Fig. 4) has216 cells arranged in one (OCV = 557 V) or two (OCV =
278 V) strings. Between every second celi there is a coolingplate through which ambient air is circulated (Fig. 5) providing a cooling power of 1.6-2 kW. For thermal insulationand mechanical support the cells are surrounded by a double walled vacuum insulation typically 25 mm thick. Lightplates made out of foamed silicon oxide take the atmosphericpressure load. This configuration has a heat conductivity ofonly 0.006 WImK and is stable for up to 1000 cc.
2.3. Battery system design
Fig. 6 i1Iustrates ali components of the complete system ready for assembly. The ohmic heater and the fan forcooling are controlled by the battery management interface(BMI) for thennal management. Plus and minus poles areconnected to a main circuit breaker that can disconnect the
battery from outside. The circuit breaker is also controlledby the BMI.
The BMI measures and supervises voItage, current, statusof charge, insulation resistance of plus and minus to groundand controls the charger by a dedicated pulse width modulated (PWM) signa\. A CAN-bus is used for the communication between the BMI; the vehic1e and the electric drive
system. Ali battery data are available for monitoring and diagnostic with a notebook.
, 1
Type
Capaci1yRated EnergyOpen Circuit Voltage0-15% DODMax. discharge currentCeli TypeIN' 01cells
Weight with BMISpecific energy wlhOllt BMI
Energy density _ BMI
Specific powerpower densrtyPeak power_ 000. 213 OCV. 3Os, 335'C
Ambient temperatureThennallossat 270'C "Iemalt~
Ah
kWh
VA
kgWM<g
WhI1
W/kgwnkW
'CW
Z5-278- Z5-557-ML-64 ML-32
64 3217.8 17.8
278.6 557224 112
ML3/2161959414816926532
·40 to +50< 110
Fig. 4. Z5C standard battery with main data.
88
AirCooling
c.-H. Dustmann/Joumal of Power Sources /27 (2004) 85-92
Thermallnsulation
+ Power
CANinterface
230 VAC
Cells
Up lo 16 battery unils in parallel (285 kWh I 51OkW)
Fig. 6. ZEBRA battery syslem.
A Multi-Battery-Server is designed for up to 16 batterypacks to be connected in parallel in a multi-battery-systemwith 285 kW h/510 kW using Z5C batteries.
2.4. Battery safety
Battery safety is essential especially for mobile applications having in mind that each battery should store as muchenergy as possible but this energy must not be released inan uncontrolled way under any conditions. Il is required thateven in a heavy accident there is no additional danger originated from the battery. On this background different testslike crash of an operative battery against a pole with 50 km/h(Fig. 7), overcharge test, over-discharge test, short circuittest, vibration test, external fire test and submersion of the
battery in water have been specified and performed [3]. TheZEBRA battery did pass ali these tests because it has a fourbarrier safety concept [4,5]:
l. Barrier by the chemistryIn case of a heavy mechanical damage ofthe battery the
brittle ceramic breaks whereas the celi case made out of
steel is deformed and most likely remains c1osed. In anycase the liquid electrolyte reacts with the liquid sodium toform salt and aluminium equal to the overcharge reactiondescribed above. These reaction products form a layer
Fig. 7. ZEBRA battery Iype Zl2-Crash TesI al 50 km!h.
covering the NiCh cathode and thus passivate il. Thisreaction reduces the thermalload by about 1/3 comparedto the total electrochemically stored energy.
2. Barrier by the celi caseThe celi case is made out of steel with glass brazed
thermo-compression bonded seal that remains c10sed fortemperatures up to about 900°C.
3. Barrier by the thermal enc10sureThe thermal insulation material of the battery box is
made out of foamed SiOz which is stable for above1000°C. In combination with vacuum like a thermo bot
tle it has a heat conductivity of only 0.006 W/mK. Thisvalue is increased only by a factor of three without vacuum. Beyond its primary function of thermal enc10sureit is a protective container for ali fault or accident conditions.
4. Barrier by the battery controllerThe battery controller supervises the battery and pre
vents it from being operated outside of specification.
3. ZEBRA battery performance
ZEBRA cells and batteries are charged in an IU-characteristic with a 6 h rate for normal charge and 1h rate for fast
charge. The voltage limitation is 2.67 V per celi for normalcharge and 2.85 V per celi for fast charge. Fast charge ispermitted up to 80% Soc. Regenerative breaking is limitedto 3.1 V per celi and 60 A per celi so that high regenerativebreaking rates are possible (Fig. 8).
The peak power during discharge, defined as the powerat 2/3 OCV, is independent of SoC so that the vehicle performance and dynamic is constant ali over the SoC range(Fig. 9). Obviously this is important for practical reasons.
3.1. Battery fife data
Battery life is specified as calendar and cycle life. Thecalendar life of I1 years is demonstrated (Fig. IO). The cyc1elife is measured by the accumulation of ali discharged chargemeasured in Ah divided by the nameplate capacity in Ah, so
C.·H. DlIstmannl Joumal oJ Power SOllrc:es /27 (2004) 85-92
V A Ah
Fast charge 1 h rating
89
2761 7.51 50
300110.60
[Voltag~
0:00 1:23 2:46 4:10Time I h
5:33 6:56
Fig. 8. Z5C battcry pcrfonnance: nonnal IU-charge in 7.5 h. 2.67 V/celi al nonnal charge 2.85 V/celi al fasi charge (up lo 80% SoC).
V A Ah
. 11°°180250200
101
150
100"n50 I ·150o l.? . o 0:00
[Voltage]
0:33 1:06Time I h
1:40 2:13
Fig. 9. Z5C Discharge-pcak power al 2/3 OCV indepcndenl of Soc.
SM3 Calendar life test (OCV hold at ToC)
•••••.•" ••Dischargc I: 19 lune 1991
--Discharge 22: 23 March 1993
-- Discharge 56: Il March 2002
35~a..§. 30
CI.I
g 25m
Ui'iij 20
CI.I
CI:
= 15CI.I
O
~ IOCI.I
:E 5
.-r,......,.·· .•.••..~1
This battery has been on test far 10.7 years, periodicallyelectrically and thermally cycled with no celi failures, nodeterior~tion in performance or loss of capacity.It has campleted 8 thermal cyctes in total.
. ~
O
O 5 IO 15 20
Capacity (Ah)
25 30 35
Fig. IO. Calendar life lesl-developmenl of mcan celi resislance.
90 c.-H. Dustmann/Joumal oJ Power Sources 127 (2004) 85-92
20 "'T"'* •••••• IIWIII ••••••••••••••••••••••••••••••••• - •••••••• JiI •••••••••••••••••••••••••••
i l4j-=-=--=-=-=-= =---=--=--::- - - - - -
;;; 12 ._ •• _:-- ••••••••...•• _ •••••• It"'•••• -~o;n-"'"--; ••::: -"•••.. ·V··· -c:: lO -- ---
'iJ - - - - ---- '--r- --- i
';; 8 ~.-..-._-~-+-_.--....~ ...~......-....--::'& 6 ... mmmmm!v ';>
< 4
ML /48 Failure Crileria 20% Oegradalion al 80% 000
FebruarYmm_m2 + 1997mmm
100
90807060
~
50
~"G'"Do.40
'"u30 20IO
o
4000
Feb
2002
3500300025002000
• 80% Pulsc Rcsislancc
1500
~ 5% Pulse Resislance
..•.- Capacity (% nameplale)
1000500
o
O
18
a 16::
Nameplate Capacity Cycles
Fig. Il. Life cycle leSI results of MU4B modules.
that one nameplate cycle is equivalent to a 100% dischargecycle. This is a reasonable unit because of the 100% Ahcfficiency of the system. Furthermore 100% of the nameplatecapacity is available for use without inftuence on batterylife. The expected cycle life is up to 3500 nameplate cycles(Fig. Il) from modulc tests and 1450 nameplate cycles frombattery testing (Fig. 12) that simulated ali reallife operationconditions. The thcrmal insulation is stable for more than
15 ycars (Fig. 13).
3.2. Recycling
Nowadays every product that is introduced to the markethas to bc rccycled at the end of its usage. ZEBRA batteriesare dismantled. The box material is stainless steel and Si02.Both of which are recycled into established processes. Thecells contai n Ni, Fe, salt and ceramic. For recycling theyare simply added to the steel melting process of the stai nless steel production. Ni and Fe contribute to the material
Z5-341 (M L01-F)
---+- R_ini
____ R_coot80%ECNIifecy~le test. ___
----.- R.,peBk80%
!
,____ .. _ ThermCycI.
o
Tamp_stano
o,o p. oo I L~R
Q ~~_CapacityIP".. o l' I o
c0_ o ~ o 0009
~••• 1 ~--I
I "I ~ twin faìlures at cycle 211
,Il twin
!.I-J 110 ~ r-~ e<>11
1 twìn al 213 directly afteronly C2I
I.f~ìl~:.e .I ""Il" !, I overdischarge lo 135 % DODdi"chmge" for 37 I
).~nomin;)1 ~I 107 cells nominaiIn' cy cle~__.._.....J
, li! '
........... -..-...................I-
I ~~~}I'I
,
,----
~l. o----IV---
- i--~ I '?~
II
II
I
II,
II l~.1Ir:J~
Vì\Il: \..........1~
I.no -'"Il./k .--!-I----.../'l 1'- --.===, ~..•.. "'[)I(
~...•.. ---*.--..-- \-
~i ...•.'y--I1\ ~ I
I
,
40
38
36
34
~~~ E-~~UCeroiM~~~22~UwroE 18~C 16
141210
8o 100
.1200 300 400 500 800 700 800
Nameplate cycle
900 1000 1100 1WO 1300 1400
320
300280260
'-'"
240 ~220 ~ >-20013 ro180
a.ro()160 ~ ()140 :.... ~•..
120 .3 ro...100 ~a.
80
E~I-60
4020
o1500
Fig. 12. Life cycle tesI resulls of banery Z5-341.
c.-H. DUSlmann/ Journal DJ Power Sources 127 (2004) 85-92 91
Fig. 13. Calendar lire test or battery tray insulation: pressure increase andhcat loss.
Z5/169 Pressure aver time at 330°C1·
0,1
0,01
0,001
10 100
Tlme I days
1000
150
140
130
120 ~
110 :::o100 ::
IO
90 ~
80
70
60
10000
tion area by a monorail system that links ali parts of the factory. A barcode system has been introduced for monitoringand backtracking of ali production parameters from the startof ceramic powder production to the battery even after usage.
4.2. Cell assembly line
The celi assembly line has been supplemented by a continuously opcrating celi case line and the current collectorwelding linc with a bending station and a brazing stationwhich lìnishes the ready-to-use current collector. The newequipment is already designed for higher production in thenext phase of production capacity build-up. This was alsoan important progress for cost reduction.
'-" production and the ceramic and salt is we\come to form thcslag. The recycling is certificated and cost effective.
4. Production
Ali ZEBRA battery production equipment is now concentrated in Stabio, Switzerland (the beta-powder line will movefrom Derby to Stabio before the end of the year 2002) witha production capacity of 2000 battery packs (equivalent to40 MW h) per year. The plant is subdivided into three parts.
4.1. Ceramic production
A new rotary press has been installed and linked by aconveyor to the new shuttle kiln which is equipped with automatic handling systems for loading and unloading. Aftersintering the beta-tubes are moved to the cutting and inspec-
4.3. Battery assembly fine
Ali battery components were redesigned for cost andweight reduction. New electrical test equipment and furnaces have been installed in order to increase the capacity for battery acceptance testing. The battery controllerand its software is redesigned and tested. It includes a"Life-Data-Memory" which stores ali relevant battery dataduring battery life like a black box.
5. Applications
The ZEBRA battery system is designed for electric vehicles, which require a balance of power to energy of abouttwo, e.g. a 25 kW h battery has about 50 kW peak power.Other applications are electric vans, buses and hybrid buseswith ZEV range (as shown in Fig. 14).
TH!
. , Hybrid Sus' in ItalyElectric Sus with 140 miles range in California
Fig. 14. Electric and hybrid vehicles equipped with ZEBRA batteries.
92 C.-H. DlIslmann/Jollmal oJ Power SOllrces 127 (2004) 85-92
The present generation of ZEBRA batteries is not applicable for hybrid vehicles that have a small battery of about3 kW h but high power up to 60 kW (a power to energy ratioof 15-20).
Recently also prototypes for stationary applications havebeen designed. These have great advantages in hot climateand for frequent cycling where the life span of conventionalbatteries is reduced such that the two to three times higherprice of ZEBRA batteries is overcompensated by its muchlonger life resulting in lower life cycle cost and avoiding theexchange ofbatteries. For UPS applications the fioat voltageof 2.61 V per celi for ZEBRA has been established.
6. Summary
The first ZEBRA battery plant has been built in Stabio,Switzcrland and the industrialisation of this battery technology has been started. A production capacity of 2000 battery packs (equivalent to 40 MW h) per year is establishedin the first phase. This has resulted in cost reductions that
,
make life-cycle-cost of ZEBRA batteries less than those oflead-acid batteries. Recently, ZEBRA batteries have beenadapted to other applications than e1ectric vehicles in addition. Now electric vehicles are going to become an optionfor urban traffic about 100 years after their first period ofsuccesso
References
[I] J.T. Kummer, in: H. Reiss, J.O. McCaldin (Eds.), Beta-Alumina Elec
trolytes. Pergamon Presso New York, t972. pp. 141-175.[2] J.L. Sudworth, A.R. lilley, The Sodium Sulphur Battery, Chapman
& Hall, London, 1985.
[3] H. B6hm, R.N. Bull, A. Prassek, ZEBRA's Response to the NewEUCARlUSABC Abuse Test Procedures, EVS-15, Brussels, 29
September-3 October 1998.[4] A.V. Zyl, C.-H. Dustmann. Safety Aspects of ZEBRA High Energy
Batteries, evt95. Paris, 13-15 November 1995, p. 57.
[5] D. Trickett. Current Status of Health and Safety Issues of
SodiumlMetal Chloride (ZEBRA) Batteries. National Renewable En
ergy Laboratory Report TP-460-25553, 1998.
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