Electrolyte system for lithium batteries, the use thereof,...

Chemistry: electrical current producing apparatus – product – and – Current producing cell – elements – subcombinations and... – Include electrolyte chemically specified and method

Reexamination Certificate

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C429S331000, C429S336000

Reexamination Certificate

active

06489064

ABSTRACT:

BACKGROUND OF THE INVENTION
The invention relates to electrolyte systems for lithium batteries with enhanced safety, their use, and a method for enhancing the safety of lithium batteries.
Portable high-value electronic devices, such as mobile telephones, laptop computers, camcorders, etc. are enjoying a very fast growing market. An adequate electrical supply for these devices requires light, high-capacity and high-quality power sources. For environmental and economic reasons, secondary rechargeable batteries are overwhelmingly used. There are essentially three competing systems: nickel cadmium, nickel metal hydride, and lithium ion batteries.
A very interesting field of use, particularly for the latter battery system, could be that of electrically operated vehicles.
Due to its outstanding performance characteristics, the lithium battery has already acquired large market shares, although it was introduced in its current state of the art only in 1994. Despite the triumphant success of the secondary lithium battery, one cannot overlook the fact that from a safety aspect it still is susceptible to improvement with respect to certain requirements.
Rechargeable lithium batteries typically contain a lithium oxide and metal oxide compound as the cathode (e.g., Li
x
MnO
2
or Li
x
CoO
2
) and lithium metal as the anode. The lithium is preferably used in the form of an intercalation compound with graphite or with carbon or graphite fibers. An overview of the use of such batteries is given by K. Brandt (Solid State Ionics 69 (1994), 173-183, Elsevier Science B.V.).
In accordance with the current state of the art, the electrolyte liquids, which are used to achieve high conductivity, are solvent mixtures of at least two or more components. The mixture must contain at least one strongly polar component, which due to its polarity has a highly dissociative effect on salts. The polar components that are typically used are ethylene carbonate or propylene carbonate. These highly polar solvents are relatively viscous and usually have a relatively high melting point, e.g., 35° C. for ethylene carbonate. To ensure adequate conductivity even at lower temperatures of use, one or more low-viscosity components are generally added as “thinners.” Typical thinners include, for instance, 1,2-dimethoxyethane, dimethyl carbonate or diethyl carbonate. Usually the thinner is added in a proportion of 40-60% of the total volume. A serious problem of these thinner components is their high volatility and their low flash point. For instance, 1 ,2-dimethoxyethane has a boiling point (BP) of 85° C., a flash point (FP) of −6° C. and an explosion limit ranging from 1.6 to 10.4% by volume. The same parameters for dimethyl carbonate are: BP 90° C., FP 18° C. For these “thinners” there are currently no equivalent substitutes.
Since the electrochemical use of electrolyte solutions and, to a far greater extent, the occurrence of faults (short circuits, overcharging, etc.). always generates heat, this implies—particularly if a cell bursts open and solvent spills —a risk of ignition with correspondingly serious consequences. The currently used systems basically avoid this by costly electronic controls. Nevertheless, some accidents caused by fire have become known, particularly during manufacture where large amounts of solvents are handled, but also during the use of rechargeable lithium batteries.
A greater source of risk during use is created in electrical vehicle applications. Here, substantially greater amounts of electrolyte solution are required per energy storage device, and electronic control of many interconnected cells is far more difficult and involves correspondingly greater risks.
To enhance safety, the cathode and anode space can be separated by a microporous separator membrane, which is made in such a way that the current flow is interrupted by the melting of the pores when a certain temperature limit is exceeded.
The safety of lithium batteries can be further enhanced by pressure relief devices that respond to gas development if the battery is overcharged and, as mentioned above, by electronic monitoring and control devices.
Also recommended are flame-retardant additives containing phosphorus and halogen, which, however, often have a negative effect on the performance characteristics of the batteries.
All of these measures, however, cannot exclude that the highly volatile and flammable “thinners” are ultimately ignited in case of malfunctions and after rupture of the cell cause a fire that is difficult to control with common extinguishing agents. Burning lithium reacts violently not only with water but also with carbon dioxide, which is commonly found in commercially available extinguishers.
The following documents represent the state of the prior art:
JP-A-7 249432=D1
EP-A-0 631339=D2
EP-A-0 599534=D3
JP-A-10064584=D4
U.S. Pat. No. 5,169,736=D5
B. Scrosati, ed., 2nd International Symposium on Polymer Electrolytes, Elsevier, London and New York (1990)=D6
U.S. Pat. No. 5,393,621=D7
JP-A-6 020719=D8
U.S. Pat. No. 4,804,596=D9
U.S. Pat. No. 5,219,683=D10
JP-A-5 028822=D11, and
EP-A-0 821368=D12
D1 and D2, for instance, propose highly fluorinated ether as the electrolyte solvent or as additives to other electrolytes. In general, these substances are thermally and chemically very stable and have high flash points. However their solvent power is far too low for the required lithium electrolyte salts, so that they cannot be used alone, and they are poorly miscible with conventional battery solvents.
Partially fluorinated carbonates are also described as electrolytes having an increased flash point (D3). The problem here is that the compounds, which are apparently suitable based on their low viscosity, have only a moderately increased flash point (37° C.). Their electrical conductivities are clearly below those of the prior art, provided that the measurements disclosed in D3 were taken at room temperature, which is likely, since no measuring temperature was specified.
Amides are also described as thinners for anhydrous electrolytes, e.g., in D4. But the suitable representatives of this class of substances based on their higher boiling point and flash point, e.g., N,N-dimethylacetamide, are so viscous that they can at best be added in small percentages and do not act as a “thinner component” in the proper sense.
D8 discloses ester compounds of the formula R
1
COOR
2
as electrolytes for secondary lithium batteries, in which at least one of the groups R
1
and R
2
has a fluorine substitution. A preferred compound is trifluoroacetic acid methyl ester. However, this compound has a boiling point of only 43° C. and a flash point of −7° C., which presents a high safety risk in case of damage.
According to the present state of the art, reduced flammability of the electrolyte solution is primarily achieved by increasing the viscosity of the electrolyte solution with the aid of binders or fillers or the use of polymer electrolytes, which are practically solid at room temperature.
D5, for instance, describes organic or inorganic thickeners (polyethylene oxide, SiO
2
, Al
2
O
3
and others) for solidifying liquid electrolyte solutions.
Polymer electrolytes composed of macromolecules with numerous polar groups, such as polyethylene oxide, as they are known from D6, are also far less flammable due to their low volatility.
One also frequently finds diacylated diols or monoacylated diol monoalkyl ethers in which the acyl component carries a double bond (i.e, is, for example, an acrylic or methacrylic acid) as the monomer components for the formation of such a gel-like polymer electrolyte. Examples of this include references D11 and D12.
D7 describes polymer electrolytes comprising polar macromolecules formed by polymerization of organophosphorus compounds, which are characterized by their particularly low flammability.
All of these gel-like to solid electrolytes have in common that due to their high viscosity, the mobility of the ions of

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