1. Field of the Invention
The present invention generally relates to the conversion of chemical energy to electrical energy. More particularly, the present invention relates to the use of a lithium/fluorinated carbon, for example, a Li/CFx cell, as a power source for an implantable medical device. Such applications require the cell to discharge under a light load for extended periods of time interrupted from time-to-time by pulse discharge. Specifically, the cell is ideal for use in an implantable cardioverter defibrillator.
2. Prior Art
Currently, implantable cardioverter defibrillators (ICD's) are powered by lithium/silver vanadium oxide (Li/SVO) cells. This chemistry provides excellent high-rate pulsing capability. Despite their high power, however, Li/SVO cells demonstrate time-dependent resistance growth during middle-of-life under some usage conditions. This resistance growth can reduce the ability of the cell to deliver energy as quickly as desired. Ideally, ICD's require a cell chemistry whose performance is easily predictable and not time-dependent.
An exemplary chemistry that meets these requirements is of a lithium/carbon monofluoride couple (Li/CFx). This system is currently used to power implantable medical devices with intermediate power requirements. Despite its excellent stability, however, the Li/CFx system has not been used for demanding applications such as ICD's because it is not believed to have sufficient power capability. Existing Li/CFx cell technology has a maximum power capability of 0.05 W/cc. The limited power capability is a direct result of low electrolyte conductivity (<1×10−2 S/cm at 37° C.), high electrical resistivity of the cathode matrix (>50 ohm*cm), and a low anode-to-cathode interface area of 5 cm2 to 20 cm2.
In that respect, the present Li/CFx cell addresses each one of these areas. The result is a Li/CFx cell that is ideally suited for demanding high current pulsatile applications, such as those needed to power an implantable cardioverter defibrillator, and the like.
These and other aspects and advantages of the present invention will become increasingly more apparent to those skilled in the art by reference to the following description read in conjunction with the appended drawings.
The term depth-of-discharge (DoD) is defined as the ratio of delivered capacity to theoretical capacity times 100.
The term “pulse” means a short burst of electrical current of significantly greater amplitude than that of a pre-pulse current immediately prior to the pulse. A pulse train consists of at least one pulse of electrical current. If the pulse train consists of more than one pulse, they are delivered in relatively short succession with or without open circuit rest between the pulses. An exemplary pulse train may consist of four 10-second pulses (23.2 mA/cm2) with about a 10 to 30 second rest, preferably about 15 second rest, between each pulse. A typically used range of current densities for cells powering implantable medical devices is from about 15 mA/cm2 to about 50 mA/cm2, and more preferably from about 18 mA/cm2 to about 35 mA/cm2. Typically, a 10-second pulse is suitable for medical implantable applications. However, it could be significantly shorter or longer depending on the specific cell design and chemistry. Current densities are based on square centimeters of the cathode electrode.
An electrochemical cell that possesses sufficient energy density and discharge capacity required of implantable medical devices comprises an anode of active materials selected from Groups IA, IIA and IIIA of the Periodic Table of the Elements. Lithium is preferred and its alloys and intermetallic compounds include, for example, Li—Si, Li—Al, Li—Mg, Li—Al—Mg, Li—B and Li—Si—B. The form of the anode may vary, but typically it comprises a thin sheet or foil of lithium metal or an alloy thereof, contacted to an anode current collector. The current collector includes an extended tab or lead for connection to the negative terminal.
The cathode comprises fluorinated carbons that are prepared from fluorine and carbon including graphitic and non-graphitic forms of carbon, such as coke, charcoal or activated carbon. The fluorinated carbon is represented by the formula (CFx)n, wherein x varies between about 0.1 to 1.9 and preferably between about 0.5 and 1.2, and (C2F)n, wherein the n refers to the number of monomer units which can vary widely. In that respect, throughout this specification the term “CFx” is meant as a general reference to fluorinated carbons including those of the formula (C2F)n.
A preferred fluorinated carbon material is described in U.S. Patent Application Pub. No. 2004/0013933—Fluorinated Carbon For Metal/Fluorinated Carbon Batteries, the disclosure of which is incorporated herein by reference. The preferred properties of the CFx material are shown in Table 1. Carbon materials with these properties are desirable for all implantable battery applications using high conductivity electrolytes. This includes hybrid cathodes having the sandwich cathode configuration: SVO/CFx/SVO, as described in U.S. Pat. No. 6,551,747 to Gan.
The CFx active material is preferably mixed with a conductive diluent and a binder material to provide a cathode mixture having an electronic resistivity of less than about 50 ohm*cm when measured without the current collector. The conductive material is added separately and mixed therewith or it is coated or deposited onto the CFx material. Examples of suitable conductive materials include any carbon containing a sp2-hybridized carbon, such as carbon black, expanded graphite, carbon fibers, single-walled carbon nanotubes, multi-walled carbon nanotubes, and the like. The conductive carbon material can be partially fluorinated to provide additional electrochemical capacity while retaining some sp2-hybridized bonds and some conductive character.
In another embodiment, the conductive material is a conductive metal that is not oxidized at potentials above 3.0 V versus lithium. Examples include, but are not limited to, silver, gold, aluminum, or titanium. The metal is preferably in a powder form.
Regardless its form, the quantity of conductive material should be as small as possible to maximize the amount of active CFx material in the cell. In that respect, the conductive material is present in quantities as high as about 20% by weight, but more preferably is at about 5%, or less. A lower resistivity or higher conductivity means that the cathode is capable of providing higher power at beginning-of-life before the CFx becomes conductive as a result of discharge.
Examples of appropriate binders include PVDF, PTFE, polyethylene (UHMW), styrene-butadiene rubber, cellulose, polyacrylate rubber, and copolymers of acrylic acid or acrylate esters with polyhydrocarbons such as polyethylene or polypropylene. The binder is preferably present at from about 1 to 5 weight percent of the cathode mixture.
In another embodiment, a conductive polymer containing a conjugated n-system, such as polypyrrole, polythiophene, or polyaniline, is used as both a binder and a conductive additive. In all cases, the conductive polymer is mixed with the CFx active material or applied thereto in order to provide the minimum possible cathode resistivity.
The cathode is preferably prepared by contacting a dry mixture of from about 90 to about 98 weight percent of the fluorinated carbon active material, up to about 5 weight percent of a conductive diluent and about 1 to 5 weight percent of a polymeric binder onto a current collector. The current collector is made of titanium, aluminum, stainless steel or carbon and is in the form of a foil, chemically-etched screen, expanded metal, punched screen, or perforated foil. The current collector is preferably coated with carbon, noble metals or a carbide-type coating. This provides a stable resistance at the electrochemical interface of the current collector with the CFx. The dry CFx mixture can also be extruded or coated onto a non-binding substrate to form a free-standing sheet that is subsequently punched to size and applied to the current collector by pressing. Alternatively, the cathode mixture in the form of a slurry or paste is applied to a foil or perforated foil, and then the cathode is dried. Regardless the preparation method, the cathode is compressed or calendered to the minimum thickness without detrimentally affecting the cell's power capability. This corresponds to an apparent cathode matrix density of about 1.2 g/cc to about 2.0 g/cc. The amount of cathode material is from about 10 mg/cm2 to about 200 mg/cm2.
The cell is prepared in either a jelly-roll or parallel multi-plate configuration. The cathode is overlaid with the anode with one or two layers of separator interspersed between them. The anode capacity is from about equal to that of the cathode capacity to about 30% greater than that thereof. The total contact area between the anode and cathode is from about 50 cm2 to 500 cm2.
Examples of separator materials include polyethylene or polypropylene, single and multi-layer, woven and non-woven with a thickness of from about 10 microns to about 30 microns. The separator must exhibit a high ionic conductivity and preferably has a melting or shutdown characteristics below the melting point of lithium, which is at about 180° C. The separator is wound between the anode and the cathode or heat-sealed around one or both of them. The total anode surface area and cathode surface area are similar to each other, although either the anode or the cathode can be slightly larger than the other.
The cell stack is then inserted into a stainless steel, steel-plated nickel, or titanium open ended container and one of the anode and the cathode current collectors is welded thereto. In the case of a case-negative design, the anode is welded to the container, but a case-positive design is also possible. The container can be cylindrical in shape or of a prismatic shape containing at least two parallel walls. A lid with a hermetically-insulated terminal pin is then laser-welded onto the open end of the container to form a casing. Alternatively, the casing is assembled from two shallow-drawn pieces, one with a hermetically insulated feedthrough, in a “clam-shell” type configuration. In any event, electrolyte is added via a fill hole. The electrolyte weight is from about 30% to about 130% of the CFx weight. The cell is then welded shut.
The electrolyte conductivity should be greater than about 1×10−2 S/cm at 37° C. Examples of appropriate electrolyte solvents include lactones, esters, carbonates, sulfones, sulfites, nitrites and ethers. Some specific examples are γ-butyrolactone, ethylene carbonate, propylene carbonate, dimethyl carbonate, diethyl carbonate, ethyl methyl carbonate, vinylene carbonate, tetrahydrofuran, dioxolane, dioxane, dimethoxyethane, and mixtures thereof. The electrolyte solvent system can be a single solvent or a mixture of one or more of the above solvents. Examples of appropriate salts include LiBF4, LiPF6, LiAsF6, LiN(SO2CF3)2, LiN(SO2C2F5)2, LiB(C2O4)2, and mixtures thereof. The salt concentration should be between about 0.5 M and about 1.5 M. A single salt or a combination of salts can be used. A preferred electrolyte combination is 1M LiAsF6 in PC:DME (1/1) or EC:DME (1/1), by volume.
ICD's specifically require very high pulse currents of greater than about 10 mA/cm2 of cathode surface area. In order to meet the requirements of these demanding applications, it is critical that the anode passivation film be stable over time. This means that the composition of the anode passivation film must provide electronic insulation while providing minimal resistance to ion flow between the anode and the electrolyte. Failure to meet these requirements results in unacceptably high internal cell resistance for ICD and other high-rate applications. Therefore, the formation of a stable passivation film requires the correct choice of electrolyte and CFx material. Since conventional practice does not require high current pulses from a Li/CFx system, such cells have typically been activated with relatively low conductivity electrolytes.
This is illustrated in
In particular, the curve having the numerical designation 10 was constructed from the background load of a Li/CFx cell comprising a prior art non-fibrous fluorinated carbon made from a petroleum coke material activated with 1M LiBF4 in GBL while the curve labeled 12 was from a similarly constructed Li/CFx cell activated with an electrolyte of 1M LiAsF6 in a 50/50 mixture, by volume, of PC/DME. The curves labeled 14 and 16 were constructed from the respective cells discharged by attaching a resistor selected to provide a 12 month discharge time to 100% DoD. The cells were then pulsed once per month at 2 mA/cm2 of cathode surface area for 10 seconds.
While both prior art Li/CFx cells have acceptable anode passivation properties and are capable of being pulse discharged because their internal resistance is roughly constant throughout life, they are not suitable for high rate applications, such as required in an ICD, and the like. It should be noted that the cell used to construct curve 16 reached its end of discharge prematurely. This graph shows that merely activating a Li/CFx cell comprising a non-fibrous fluorinated carbon with a high pulse electrolyte system of 1M LiAsF6 in a 50/50 mixture, by volume, of PC/DME, which is preferred for high pulse Li/SVO cells, does not result in a high pulsatile Li/CFx cell. Not only must the electrolyte be capable of supporting high current pulses, but the fluorinated carbon must be tailored accordingly as well.
Conversely, the use of an electrolyte having conductivity greater than about 1×10−2 S/cm reduces the cell's internal resistance at beginning-of-life and provides a higher loaded voltage and power. During discharge, however, the anode passivation film becomes thicker, resulting in increasing resistance with discharge. The power capability of such a Li/CFx cell becomes unacceptably high toward end-of-life. Such performance is particularly the case with CFx materials derived from petroleum coke or graphite.
Therefore, an important aspect of the present invention is that an electrolyte having a relatively high conductivity greater than about 1×10−2 S/cm at 37° C. is used in conjunction with a CFx material derived from a carbon fiber. The fibrous CFx material is ground to a typical aspect ratio between about 2 and about 25. The aspect ratio is defined as the length of the fiber divided by its diameter. This type of carbon material is useful with both low and high conductivity electrolytes without creating anode passivation problems.
The graph illustrated in
In particular, curve 20 was constructed from the background load of present invention Li/CFx cell comprising a fibrous fluorinated carbon activated with 1M LiBF4 in GBL while the curve labeled 22 was from a similarly constructed Li/CFx cell activated with an electrolyte of 1M LiAsF6 in a 50/50 mixture, by volume, of PC/DME. The curves labeled 24 and 26 were constructed from the respective cells discharged by attaching a resistor selected to provide a 12 month discharge time to 100% DoD. The cells were then pulsed once per month at 2 mA/cm2 of cathode surface area for 10 seconds. This graph shows that while a traditional Li/CFx cell electrolyte of 1 M LiBF4 in GBL activating a fibrous fluorinated carbon cathode material exhibits acceptable background and pulse discharge characteristics, the best results are with the cell that has both the high conductivity electrolyte and the fibrous fluorinated carbon material (curves 22, 26).
Therefore, an electrochemical cell incorporating a CFx material derived from a carbon fiber of the defined aspect ratio activated with a high conductivity electrolyte (having a conductivity greater than about 1×10−2 S/cm at 37° C.) provides high current pulses with high loaded voltage throughout discharge, even after having been discharged over many years at 37° C. Such a cell is unknown in conventional practice and, therefore, suitable for ICD applications.
As defined by equation 1, the combination of a conductive electrolyte and a conductive cathode matrix results in an internal cell DC resistance of less than about 70 ohms×cm2 of cathode surface area at beginning-of-life. Preferably, the internal DC resistance is less than about 50 ohms×cm2.
where pulse length=10 seconds
The cell exhibits the typical excellent long-term stability and predictability of the CFx system, as well as its high energy density (greater than about 300 Ah/cc, greater than about 600 Wh/cc). Additionally, the cell is capable of delivering about 0.5 W/cc of cathode volume for greater than 5 seconds with a voltage above 1.70 V.
This is illustrated in
Another aspect of the present Li/CFx cell is that it is capable of delivering greater than about 10% of its useful capacity between about 2.7 volts and 2.3 volts when discharged over a period of six months, or more. Implantable medical devices typically use background voltage as a means of indicating when the cell needs to be replaced. A typical indicating voltage is at 2.7 volts measured at the device background discharge load, which is typically observed after about 5 to 10 years of discharge under load. Upon reaching the replacement indicating voltage, there must be sufficient time and discharge capacity before the cell is no longer capable of providing enough power for the medical device to function properly, which typically occurs at about 2.3 volts.
As shown in
Preferably, the power source for an implantable medical device has a more rounded discharge profile at end-of-life. This allows for more flexible and accurate placement of the replacement indicator voltage. Thus, another attribute of the present invention is that the CFx material and electrolyte combination provide a more gradual voltage drop at end-of-life. This is illustrated in the graph in
The rate of an electrochemical reaction in an electrochemical cell is partially determined by the contact area between the anode and cathode. This is termed the electrode interfacial surface area. Increasing the contact area reduces the rate of the electrochemical reaction occurring at the interface between the opposite polarity electrodes, thus reducing the over-potential associated with the discharge reaction. It is known that Li/CFx cells for ICD applications need an electrode interfacial surface area in excess of about 50 cm2, but less than about 500 cm2. Cells within this range have adequate pulse capability and are still manufacturable in sufficiently small sizes required for implantable medical applications. In that respect, the ratio of the electrode interfacial surface area to the external cell volume for the present Li/CFx cell is greater than about 15 square centimeters per cubic centimeter of casing volume (cm2/cm3), but less than about 50 cm2/cm3. A preferred casing size is from about 1 cm3 to about 10 cm3.
Another aspect of the present Li/CFx cell is that from about 1% to about 20% of the cell's theoretical capacity is removed prior to use. Because of the inherent resistivity of CFx prior to discharge, Li/CFx cells exhibit relatively high internal resistance at beginning-of-life. During discharge, the CFx material is converted to carbon, resulting in a significant enhancement in conductivity of the cathode matrix and a reduction in cell internal resistance. According to conventional practice, Li/CFx cells are discharged to about 1% DoD during manufacturing burn-in in order to reduce internal resistance to a level acceptable for relatively light load pacing functions, and the like, for example, the heart sensing and pacing functions that require electrical current of about 1 microampere to about 100 milliamperes. In order to maximize the pulse capability (electrical current of about 1 ampere to about 5 amperes) at beginning-of-life for high current applications, for example, during charging of a capacitor in a defibrillator for the purpose of delivering an electrical shock therapy to the heart to treat tachyarrhythmia, the irregular, rapid heartbeats that can be fatal if left uncorrected, it is necessary to discharge the Li/CFx to about 20% DoD. While removal of this much of the cell's theoretical capacity provides maximum power capability for a high rate implantable application, it represents a significant loss of energy density. In that respect, the power requirements and the energy density requirements of a particular application need to be balanced by selecting the appropriate pre-discharge capacity in the about 1% to about 20% DoD burn-in range. By making the CFx cathode matrix as conductive as possible, the burn-in capacity that is removed can be minimized. Preferably, the cell is discharged until the internal DC resistance as defined above is less than 40 ohms×cm2. This is done by subjecting the completed cell is subjected to a discharge burn-in of from about 1% and 20% of its depth-of-discharge by applying a load to the cell for a fixed period of time. Typically, the load is chosen such that the necessary capacity can be removed in about 12 to about 24 hours. The thusly conditioned Li/CFx is now ready for use as a power source for an implantable medical device, particularly one requiring current pulse discharge applications.
It is appreciated that various modifications to the inventive concepts described herein may be apparent to those skilled in the art without departing from the spirit and the scope of the present invention defined by the hereinafter appended claims.
This application claims priority from U.S. Provisional Application Ser. No. 60/764,152, filed Feb. 1, 2006.
Number | Date | Country | |
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60764152 | Feb 2006 | US |