CA1232941A - Energy storage device - Google Patents
Energy storage deviceInfo
- Publication number
- CA1232941A CA1232941A CA000469354A CA469354A CA1232941A CA 1232941 A CA1232941 A CA 1232941A CA 000469354 A CA000469354 A CA 000469354A CA 469354 A CA469354 A CA 469354A CA 1232941 A CA1232941 A CA 1232941A
- Authority
- CA
- Canada
- Prior art keywords
- electrode
- carbonaceous material
- cell
- cloth
- housing
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired
Links
Classifications
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M4/00—Electrodes
- H01M4/02—Electrodes composed of, or comprising, active material
- H01M4/13—Electrodes for accumulators with non-aqueous electrolyte, e.g. for lithium-accumulators; Processes of manufacture thereof
- H01M4/133—Electrodes based on carbonaceous material, e.g. graphite-intercalation compounds or CFx
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M4/00—Electrodes
- H01M4/86—Inert electrodes with catalytic activity, e.g. for fuel cells
- H01M4/96—Carbon-based electrodes
-
- D—TEXTILES; PAPER
- D01—NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
- D01F—CHEMICAL FEATURES IN THE MANUFACTURE OF ARTIFICIAL FILAMENTS, THREADS, FIBRES, BRISTLES OR RIBBONS; APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OF CARBON FILAMENTS
- D01F9/00—Artificial filaments or the like of other substances; Manufacture thereof; Apparatus specially adapted for the manufacture of carbon filaments
- D01F9/08—Artificial filaments or the like of other substances; Manufacture thereof; Apparatus specially adapted for the manufacture of carbon filaments of inorganic material
- D01F9/12—Carbon filaments; Apparatus specially adapted for the manufacture thereof
- D01F9/14—Carbon filaments; Apparatus specially adapted for the manufacture thereof by decomposition of organic filaments
- D01F9/145—Carbon filaments; Apparatus specially adapted for the manufacture thereof by decomposition of organic filaments from pitch or distillation residues
- D01F9/155—Carbon filaments; Apparatus specially adapted for the manufacture thereof by decomposition of organic filaments from pitch or distillation residues from petroleum pitch
-
- D—TEXTILES; PAPER
- D01—NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
- D01F—CHEMICAL FEATURES IN THE MANUFACTURE OF ARTIFICIAL FILAMENTS, THREADS, FIBRES, BRISTLES OR RIBBONS; APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OF CARBON FILAMENTS
- D01F9/00—Artificial filaments or the like of other substances; Manufacture thereof; Apparatus specially adapted for the manufacture of carbon filaments
- D01F9/08—Artificial filaments or the like of other substances; Manufacture thereof; Apparatus specially adapted for the manufacture of carbon filaments of inorganic material
- D01F9/12—Carbon filaments; Apparatus specially adapted for the manufacture thereof
- D01F9/14—Carbon filaments; Apparatus specially adapted for the manufacture thereof by decomposition of organic filaments
- D01F9/20—Carbon filaments; Apparatus specially adapted for the manufacture thereof by decomposition of organic filaments from polyaddition, polycondensation or polymerisation products
- D01F9/21—Carbon filaments; Apparatus specially adapted for the manufacture thereof by decomposition of organic filaments from polyaddition, polycondensation or polymerisation products from macromolecular compounds obtained by reactions only involving carbon-to-carbon unsaturated bonds
- D01F9/22—Carbon filaments; Apparatus specially adapted for the manufacture thereof by decomposition of organic filaments from polyaddition, polycondensation or polymerisation products from macromolecular compounds obtained by reactions only involving carbon-to-carbon unsaturated bonds from polyacrylonitriles
-
- D—TEXTILES; PAPER
- D01—NATURAL OR MAN-MADE THREADS OR FIBRES; SPINNING
- D01F—CHEMICAL FEATURES IN THE MANUFACTURE OF ARTIFICIAL FILAMENTS, THREADS, FIBRES, BRISTLES OR RIBBONS; APPARATUS SPECIALLY ADAPTED FOR THE MANUFACTURE OF CARBON FILAMENTS
- D01F9/00—Artificial filaments or the like of other substances; Manufacture thereof; Apparatus specially adapted for the manufacture of carbon filaments
- D01F9/08—Artificial filaments or the like of other substances; Manufacture thereof; Apparatus specially adapted for the manufacture of carbon filaments of inorganic material
- D01F9/12—Carbon filaments; Apparatus specially adapted for the manufacture thereof
- D01F9/14—Carbon filaments; Apparatus specially adapted for the manufacture thereof by decomposition of organic filaments
- D01F9/32—Apparatus therefor
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M4/00—Electrodes
- H01M4/02—Electrodes composed of, or comprising, active material
- H01M4/13—Electrodes for accumulators with non-aqueous electrolyte, e.g. for lithium-accumulators; Processes of manufacture thereof
- H01M4/139—Processes of manufacture
- H01M4/1393—Processes of manufacture of electrodes based on carbonaceous material, e.g. graphite-intercalation compounds or CFx
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/05—Accumulators with non-aqueous electrolyte
- H01M10/052—Li-accumulators
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
Landscapes
- Chemical & Material Sciences (AREA)
- Engineering & Computer Science (AREA)
- Chemical Kinetics & Catalysis (AREA)
- General Chemical & Material Sciences (AREA)
- Electrochemistry (AREA)
- Textile Engineering (AREA)
- Materials Engineering (AREA)
- Manufacturing & Machinery (AREA)
- Oil, Petroleum & Natural Gas (AREA)
- Battery Electrode And Active Subsutance (AREA)
- Secondary Cells (AREA)
- Cell Electrode Carriers And Collectors (AREA)
- Carbon And Carbon Compounds (AREA)
- Vessels And Coating Films For Discharge Lamps (AREA)
- Piezo-Electric Or Mechanical Vibrators, Or Delay Or Filter Circuits (AREA)
Abstract
ABSTRACT OF THE DISCLOSURE An electrode suitable for use in energy storage devices is described which is made of an assembly of an electrically conductive carbonaceous material having conjugated and preferably polybenzenoid plate-like structures. The carbonaceous material has a Youngs modulus of greater than 1,000,000 psi. The so-defined electrode material does not undergo a substantial change in dimension during repeated electrical charge and discharge cycles. Additionally there is described an energy storage device utilizing the above described electrode.
Description
123~9~1 4693-3536 SECONDARY ELECTRICAL ENERGY STORAGE DEVICE
AND ELECTRODE THEREFOR
The invention resides in the use of a carbonaceous material in conjunction with an electron collector as an electrode for secondary electrical energy storage devices. The carbonaceous ma-terial of the electrode, is stable in the presence of an electrolyte system containing anions such as perchlorates, hexafluoroarsenates, and the like, under ambient or normal operating temperatures of use of the electrode.
That i5 to say, the carbonaceous material does not appreciably irreversibly swell or contract during deep electrical charge and discharge cycles such as may be performed in the operation of a secondary electrical energy storage device.
' Numerous patents and technical literature describe electrical energy storage devices utilizing a carbonaceous material such as carbon or graphite as an electrode material. Of course, one of the earliest of these devices was the Laclanche' battery of 1866 wherein carbon was used as an electron collector in a 20~ Zn/NH4Cl/MnO2 primary battery. Since then carbon has been used extensively as a component of the electrode 30,532-F
. .
. .
~23;~9'~
in primary batteries, Primary fuel cells, secondary fuel cells, secondary batteries and capacitors. The function of the carbon or qraphite in these aforementioned devices has been primarily that of a current collector or as a reactive material to Eorm new com-pounds with fluorine t~hich have different structures and prop-erties than the ori~inal carhon/qraphite, and most recently, as semiconductor materials which form salts with ions of the electro-lyte. These prior art devices can be categorized as: primary batteries such as is disclosed in Coleman et al. in U.S. Patent No. 2,597,451, Panasonic Lithlum Battery literature, an~ IJ.S.
Patent Nos. ~,271,242, 3,700,502, and 4,224,389; fuel cells, such as Japanese Publication ~o. 54-082043; and, secondary fuel cells, wlth limited recharqeabi]ity, such as is described in Dey et al.
U.~. Patent No. 4,037,025, a rechargeable fuel cell employin~ an activated (high surface area) qraphite; recharqeable secondary batteries (accumulators) such as is disclosed in ~art U.S. Patent No. 4,251,568 employing graphite as a current collector, and Bennion U.S. Patent Nos. 3,844,837 and 4,009,323 and capacitors such as in ~utherus et al. U.S. Patent No. 3,700,975 or German Patent No. 3,231,243 using a high surface area carbon (~raphi~e~.
Some of these devices also utilize ionizable salts dissolved in a nonconductive so]vent.
The carbonaceous materials described in the patents and in the literature are materials graphitized or carhonized until the materials become electrically conductive. These materials are derived from polyacetylenes, polyphenylenes, polyacrylonitriles, and petroleum pitch which have been heated to "carbonize and/or graphitize" the precursor material to impart ,.,, . -- - ~ -' ' , - . .:
,.
,:
'' ' - ' , . . .
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some degree of electrical conductivity. Some of -the graphites used in the prior art literature are graphites such as RPG (Reinforced Pyrolytic Graphite), R-1 nuclear reactor grade graphite, PGCP tPyrolytic Graphite Carbon Paper), and GRAFOIL (a Trademark of the Union Carbide Corporation) comprising an expanded and compressed graphite, and the like.
Doping of analogous carbonaceous materials has also been reported in Chemical and Engineering News, Volume 60, No. 16, pp. 29-33, April 19, 1982, in an article entitled "Conducting Polymers R & D Continues to Grow"; Journal Electrochem Society, Electrochemical Science, 118, No. 12, pp. 1886-1890, December 1971; and Chemical & Engineering News, 59, No. 41, pp. 34~35, October 12, 1981, entitled "Polymer Cell Offers More Power, Less Weight".
The problems attendant with these reported cells are that they do not have a long life since the electrode made from such carbonaceous material is susceptible to degradation when subjected to repeated electrical charge and discharge cycling.
For example, U.S. Patent No. 3,844,837 (Bennion et al.) describe~ a battery employing a nuclear grade graphite impregnated with chips of Li2o as the positive electrode and copper as the negative electrode in a LiCF3SO3-dimethyl sulfi-te (DMSU) electrolyte. The graphite electrode was made from a grade R-l nuclear graphite (sold by Great Lakes Carbon Company) and was reported to b~ flaky after 9 cycles of electrical charge and discharge. The patentees also tested a graphite cloth and concluded it to be unsatisfactory.
.
: ~ .
30,532-F -3~
, , , , Several other gr~phites were used with equallv unsatisfactory results with the best results o~tained from pyrolytic graphite which failed after 33 cycles. Dey et al. employs a hiqh surface area carbon or qraphitic material, ~ithin the pores of which a chemical reaction occurs, but said material ls qenerally thought to be of a low conductance throuqh lack of continuity of the carb-on surface. Further, it is believed that such materials do not maintain the flimensiona] stability and structural integrity neces-sary for the reversible formation of carbon complexes required for long rechargeable cycle Iife of secondary batteries.
Experiments conducted in the course of the development of the present invention included the use of GRAFOIL (r~rade Mark) which failed on the first electrical charqe and RPG (~uper Temp) graphite electrodes which also failed. It was found that an amount greater than 20% of the positive electrode made from RPG
qraphite was lost as flakes, chips and powder after only 27 elec-trical charge and discharge cycles.
It is to be noted that the prior art identifies the disinte~ration and damaqe to the electrode as beinq a result of a swelling and ~hrinking of the electrode body and that this swelling and shrinking increases with each electrical charqe and discharge cycle which distorts the graphite platelets which flake off due to the stress of swelling and shrinking. In conducting these experiments in the course of the development of the present invention, it was confirmed that such flaking-off of the graphite platelets occurs when the aforementioned graphite materials were subjected to repeated electrical charge and discharge cyclesO
~
~2325~i According to a first aspect, -the present invention provides an electrode for use in a secondary electrical energy storage device comprising an electrode body of electrically conductive carbonaceous material, having a skeletal orientation, at least at or near the surface, and a current collector electrically associated therewith, wherein said carbonaceous material has a Youngs modulus of greater than 1,000,000 psi (6.9 GPa) and undergoes a physical dimensional change of less than 5% during repeated electrical charge and discharge cycling.
According to another aspect, the invention provides a secondary electrical energy storage device comprising a housing having an electrically non-conductive interior surface and a moisture impervious exteriox surface or laminar body and having at least one cell positioned in said housing, each cell comprising at least one pair of electro-conductive electrodes electrically insulated from contact with each other, said housing containing a substantially non-aqueous electrolyte, wherein at least one of the electrodes of each cell is an electrode of the invention.
According to a further aspect, the invention resides in a secondary electrical energy storage device comprising a housing having an electrically non-conduc-tive interior surface and a moisture impervious outer surface or laminated body and having at least one cell positioned in said housing, each cell.comprising at least one pair of electroconductive electrodes electrically insulated from contact with each other, said housing containing a substantially non-a~ueous electrolyte, wherein each of the electrodes of each cell is an electrode 30,532-F -5-~,...................................................................... .
: ~ .
~L~32~
and wherein each said electrode has the freedom of choice of polarity on recharge and the ability to be partially and/or fully reverse polarized without harm.
The electrodes can be separated from each other by distance or by a non-electrically conductive ion-permeable material.
Ph~sical Properties Preferably, the electrically conductive carbonaceous material of the electrode should have the following physical property criteria:
(1) A Young's modulus of greater than 1,000,000 psi (6.9 GPa), preferably from 10,000,000 psi (69 GPa) to 55,000,000 psi (380, GPa), more preferably from 20,000,000 to 45,000,000 psi (138 GPa to 311 GPa).
AND ELECTRODE THEREFOR
The invention resides in the use of a carbonaceous material in conjunction with an electron collector as an electrode for secondary electrical energy storage devices. The carbonaceous ma-terial of the electrode, is stable in the presence of an electrolyte system containing anions such as perchlorates, hexafluoroarsenates, and the like, under ambient or normal operating temperatures of use of the electrode.
That i5 to say, the carbonaceous material does not appreciably irreversibly swell or contract during deep electrical charge and discharge cycles such as may be performed in the operation of a secondary electrical energy storage device.
' Numerous patents and technical literature describe electrical energy storage devices utilizing a carbonaceous material such as carbon or graphite as an electrode material. Of course, one of the earliest of these devices was the Laclanche' battery of 1866 wherein carbon was used as an electron collector in a 20~ Zn/NH4Cl/MnO2 primary battery. Since then carbon has been used extensively as a component of the electrode 30,532-F
. .
. .
~23;~9'~
in primary batteries, Primary fuel cells, secondary fuel cells, secondary batteries and capacitors. The function of the carbon or qraphite in these aforementioned devices has been primarily that of a current collector or as a reactive material to Eorm new com-pounds with fluorine t~hich have different structures and prop-erties than the ori~inal carhon/qraphite, and most recently, as semiconductor materials which form salts with ions of the electro-lyte. These prior art devices can be categorized as: primary batteries such as is disclosed in Coleman et al. in U.S. Patent No. 2,597,451, Panasonic Lithlum Battery literature, an~ IJ.S.
Patent Nos. ~,271,242, 3,700,502, and 4,224,389; fuel cells, such as Japanese Publication ~o. 54-082043; and, secondary fuel cells, wlth limited recharqeabi]ity, such as is described in Dey et al.
U.~. Patent No. 4,037,025, a rechargeable fuel cell employin~ an activated (high surface area) qraphite; recharqeable secondary batteries (accumulators) such as is disclosed in ~art U.S. Patent No. 4,251,568 employing graphite as a current collector, and Bennion U.S. Patent Nos. 3,844,837 and 4,009,323 and capacitors such as in ~utherus et al. U.S. Patent No. 3,700,975 or German Patent No. 3,231,243 using a high surface area carbon (~raphi~e~.
Some of these devices also utilize ionizable salts dissolved in a nonconductive so]vent.
The carbonaceous materials described in the patents and in the literature are materials graphitized or carhonized until the materials become electrically conductive. These materials are derived from polyacetylenes, polyphenylenes, polyacrylonitriles, and petroleum pitch which have been heated to "carbonize and/or graphitize" the precursor material to impart ,.,, . -- - ~ -' ' , - . .:
,.
,:
'' ' - ' , . . .
1~23~
some degree of electrical conductivity. Some of -the graphites used in the prior art literature are graphites such as RPG (Reinforced Pyrolytic Graphite), R-1 nuclear reactor grade graphite, PGCP tPyrolytic Graphite Carbon Paper), and GRAFOIL (a Trademark of the Union Carbide Corporation) comprising an expanded and compressed graphite, and the like.
Doping of analogous carbonaceous materials has also been reported in Chemical and Engineering News, Volume 60, No. 16, pp. 29-33, April 19, 1982, in an article entitled "Conducting Polymers R & D Continues to Grow"; Journal Electrochem Society, Electrochemical Science, 118, No. 12, pp. 1886-1890, December 1971; and Chemical & Engineering News, 59, No. 41, pp. 34~35, October 12, 1981, entitled "Polymer Cell Offers More Power, Less Weight".
The problems attendant with these reported cells are that they do not have a long life since the electrode made from such carbonaceous material is susceptible to degradation when subjected to repeated electrical charge and discharge cycling.
For example, U.S. Patent No. 3,844,837 (Bennion et al.) describe~ a battery employing a nuclear grade graphite impregnated with chips of Li2o as the positive electrode and copper as the negative electrode in a LiCF3SO3-dimethyl sulfi-te (DMSU) electrolyte. The graphite electrode was made from a grade R-l nuclear graphite (sold by Great Lakes Carbon Company) and was reported to b~ flaky after 9 cycles of electrical charge and discharge. The patentees also tested a graphite cloth and concluded it to be unsatisfactory.
.
: ~ .
30,532-F -3~
, , , , Several other gr~phites were used with equallv unsatisfactory results with the best results o~tained from pyrolytic graphite which failed after 33 cycles. Dey et al. employs a hiqh surface area carbon or qraphitic material, ~ithin the pores of which a chemical reaction occurs, but said material ls qenerally thought to be of a low conductance throuqh lack of continuity of the carb-on surface. Further, it is believed that such materials do not maintain the flimensiona] stability and structural integrity neces-sary for the reversible formation of carbon complexes required for long rechargeable cycle Iife of secondary batteries.
Experiments conducted in the course of the development of the present invention included the use of GRAFOIL (r~rade Mark) which failed on the first electrical charqe and RPG (~uper Temp) graphite electrodes which also failed. It was found that an amount greater than 20% of the positive electrode made from RPG
qraphite was lost as flakes, chips and powder after only 27 elec-trical charge and discharge cycles.
It is to be noted that the prior art identifies the disinte~ration and damaqe to the electrode as beinq a result of a swelling and ~hrinking of the electrode body and that this swelling and shrinking increases with each electrical charqe and discharge cycle which distorts the graphite platelets which flake off due to the stress of swelling and shrinking. In conducting these experiments in the course of the development of the present invention, it was confirmed that such flaking-off of the graphite platelets occurs when the aforementioned graphite materials were subjected to repeated electrical charge and discharge cyclesO
~
~2325~i According to a first aspect, -the present invention provides an electrode for use in a secondary electrical energy storage device comprising an electrode body of electrically conductive carbonaceous material, having a skeletal orientation, at least at or near the surface, and a current collector electrically associated therewith, wherein said carbonaceous material has a Youngs modulus of greater than 1,000,000 psi (6.9 GPa) and undergoes a physical dimensional change of less than 5% during repeated electrical charge and discharge cycling.
According to another aspect, the invention provides a secondary electrical energy storage device comprising a housing having an electrically non-conductive interior surface and a moisture impervious exteriox surface or laminar body and having at least one cell positioned in said housing, each cell comprising at least one pair of electro-conductive electrodes electrically insulated from contact with each other, said housing containing a substantially non-aqueous electrolyte, wherein at least one of the electrodes of each cell is an electrode of the invention.
According to a further aspect, the invention resides in a secondary electrical energy storage device comprising a housing having an electrically non-conduc-tive interior surface and a moisture impervious outer surface or laminated body and having at least one cell positioned in said housing, each cell.comprising at least one pair of electroconductive electrodes electrically insulated from contact with each other, said housing containing a substantially non-a~ueous electrolyte, wherein each of the electrodes of each cell is an electrode 30,532-F -5-~,...................................................................... .
: ~ .
~L~32~
and wherein each said electrode has the freedom of choice of polarity on recharge and the ability to be partially and/or fully reverse polarized without harm.
The electrodes can be separated from each other by distance or by a non-electrically conductive ion-permeable material.
Ph~sical Properties Preferably, the electrically conductive carbonaceous material of the electrode should have the following physical property criteria:
(1) A Young's modulus of greater than 1,000,000 psi (6.9 GPa), preferably from 10,000,000 psi (69 GPa) to 55,000,000 psi (380, GPa), more preferably from 20,000,000 to 45,000,000 psi (138 GPa to 311 GPa).
(2) An aspect ratio of greater than 100:1. The aspect ratio is defined herein as the length to diameter ~/d ratio of a fibrous or filament strand of the carbonaceous material or as the length to depth ratio when the carbonaceous material is formed as a planar sheet.
(3) The structural and mechanical integrity of the carbonaceous material in whatever fabricated form it may be (woven, knit or non-woven from continuous filament or staple fibers or a film) should be such that it does not require the presence of a support such as a pressure plate (face films or mesh) to maintain the carbonaceous material in the desired sheet or plate like shapes throughout at least 100 charge/discharge cycles.
;
30,532-F -6-' ~ ' ' :
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;
30,532-F -6-' ~ ' ' :
;: ` ' ' ; .
(4) A surface area of at least 0.1 m2/g but less than one associates with activated absorp-tive carbon, suitably less than 50 m2/g, preferably less than 10 m2/g, and more preferably less than a 5 m2/g.
(5) Sufficent integrity of the form of the carbonaceous material to enable the carbonaceous material to retain its plate or sheet like shape when of a size greater than 1 in2 (6.45 cm2) to greater than 144 in2 (930 cm2) without support other than a metallic current collector ~rame forming the edge portion of the electrode.
(6) The secondary electrical energy storage device in which -the electrode of this invention is employed should be substantially free of water to the extent o less than 100 ppm. Preferably, the water content should be less than 20 ppm and most preferably less than 10 ppm. The device of the invention is capable of operating with a water content of up to 300 ppm but will have a somewhat reduced cycle life.
Further, it is to be understood that should the water con-tent level become onerous, the device may be disassembled, dried and reassembled in such dry state without substantial damage to its continued operability.
Performance Crlteria
Further, it is to be understood that should the water con-tent level become onerous, the device may be disassembled, dried and reassembled in such dry state without substantial damage to its continued operability.
Performance Crlteria
(7) The carbonaceous material of an electrode should be capable of sustaining more than 100 electrical charge and discharge cycles without any appreciable damage due to 1aking of the carbonaceous material.
Preferably, no app.reciable damage should occur after more than 500 electrical charge and discharge cycles, : ::
30,532~F -7--' :
, .
- . . :
::
at a discharge capacity of greater than 150 coulombs per gram of carbonaceous material of an electrode.
Preferably, no app.reciable damage should occur after more than 500 electrical charge and discharge cycles, : ::
30,532~F -7--' :
, .
- . . :
::
at a discharge capacity of greater than 150 coulombs per gram of carbonaceous material of an electrode.
(8) The coulometric (coulombic) efflciency of the carbonaceous material of the electrode should be greater than 70 percent, preferably greater than 80 percent and most preferably greater than 90 percent.
(9) The carbonaceous material of the electrode should be capable of sustaining deep electrical discharges of greater than 70 percent of its electrical charge capacity for at least 100 cycles of electrical chaxge and discharge, and preferably greater than 80% for more than 500 electrical charge and discharge cycles.
Accordingly, the carbonaceous material of an electrode having the physical properties hereinbefore described preferably should be capable of sustaining electrical discharge and recharge of more than 100 cycles at a discharge capacity of greater than 150 coulombs per gram of carbonaceous material in an electrode and at a coulometric efficiency of greater than 70% without any substantial irreversible change in dimensions (dimensional change of less than about 5%).
Usually, the carbonaceous material will be obtained by heating a precursor material to a temperature above 850C until electrically conductive. Carbonaceous precursor starting materials capable of forming the electrically conductive oriented carbonaceous material ; ~ portion of the electrode may be formed from pitch (petroleum or coal tar), polyacetylene, polyacrylonitrile, polyphenylene, SARAN (Trade Mark), and the like. The carbonaceous precursor starting material should have 30,532-F -8-.~,~
, ' `~! ~ ' , ' ,. ` "
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, ' ' '':
~29~
some degree of skeletal orien-ta-tion, i.e., many of these materials either have substantial concentrations of oriented benzenoid structural moieties or moieties which are capable of conversion, on heating, to benzenoid or equivalent skeletal orientation at or near the surface because of the skeletal orientation of the starting material.
Exemplary of preferred carbonaceous precursor materials which exhibit such skeletal orientation on heating are assemblies of multi or monofilament strands or fibers prepared from petroleum pitch or polyacrylo-nitrile. Such multi or monofilament strands or fibers are readily converted into threads or yarns which can then be fabricated into a cloth-like product. One technigue for producing suitable monofilament fibers is disclosed in U.S. Patent No. 4,005,183 where the fibers are made into a yarn which is then woven into a cloth.
The cloth is then subjected to a temperature, usually above 1000C, sufficient to carbonize the cloth to make ~0 the carbonaceous material electrically conductive and so as to provide the material with the physical property characteristics hereinbefore described under paragraphs (1) through (6). Such a cloth, in con~unction with an electron collector, is particularly suitable for use as an electrode in the secondary electrical energy storage device of the present invention.
Advantageously, the carbonaceous precursor material is in the form of a continuous filament fiber, thread(s) constituted o continuous filament(s) or non-continuous fiber tow (yarn) which can be made into assemblies such as woven, non-woven, or knitted assemblies, or the staple fibers per se can be layered ~ 30,532-F -9-,. .
.
.
~:3Z~
to form a cloth, paper-like or felt-like planar member.
However, acceptable results are obtained when yarns made from short fibers, having a length of from l to lO
cm, are woven into a cloth-like product (provided such short fibers still have, when heat treated, the required physical properties hereinbefore mentioned under (1) through (6~). It is of course to be understood that while it is advantageous to form the precursor material, preferably in a stabilized state (such as is obtained by oxidation3, into the desired form (knit, woven or felt) prior to carbonization, such construction may be done after carbonization if the modulus is below about 55,000,000 psi (380 GPa) and preferably below about 39,000,000 psi (269 GPa) for machine fabrication. It is of course to be understood that the carbonaceous material may be formed from a film precursor.
The degree of carbonization and/or graphiti-zation does not appear to be a controlling factor in the performance of the material as an electrode element in an electrical storage device except tha-t it must be enough to render the material sufficiently electrically conductive and is also enough to provide the afore-mentioned physical and mechanical properties under the designated use conditions. Carbonaceous materials ; 25 having about 90 percent carbonization, are refexred to in the literature as partially carbonized. Carbonaceous materials having from 91 to 98 percent carbonization are referred to in the literature as a carbonized material, while materials having a carbonization of greater than 98 percent are referred to as graphitized.
; It has surprisingly been found that carbonaceous materials having a degree of carbonization, of from 90 to 99 percent, have failed as electrode materials unless 30,532-F -10-.
~23~
the carbonaceous material has the required dimensional stability during electrical charge and discharge cycling.
For example, ~PG graphite and GRAFOIL, while having the requisite degree of carbonization, electrical conduc-tivity and surface area, do not have the required physical properties of Young's Modulus and aspect ratio and thus have failed.
In accordance with the invention, a rechargable and polarity reversible electrical storage device can be prepared by aligning at least one pair of electrodes, made from the aforedescribed carbonaceous material and its associated electron collector (which are electrically conductive) in a housing. The housing has a non-conductive interior surface and is impervious to moisture. The electrodes are immersed in a non-aqueous (water being present in an amount of less than about 100 ppm) fluid contained in said housing. The fluid itself must be capable of forming, or contains dissolved therein, at least one ionizable metal salt. Each electrode is comprised of the carbonaceous heat-treated material, of the present invention, associated with an electron collector which is preferably insulated against contact uith the electrolyte fluid.
The secondary electrical energy storage device of the invention may be constructed without the polarity reversing capability by aligning the aforementioned electrically conductive carbonaceous fiber assembly, such as a cloth, and its electron collector as the positive electrode alternating with a negative electrode which may be constxucted of a metal, such as lithium, or a metal alloy and immersing the electrodes in a substantially non-aqueous fluid, which fluid itself is .
~ 3~,532-F -11--, capable of forming or which contains at least one ionizable soluble metal salt dissolved therein to provide electrolyte ions~
In the construction of a preferred embodiment of the secondary electrical energy storage device of the present invention, conventional porous separators of fiberglass, polymeric materials, or composites of polymeric materials, may ~e and are preferably employed to separate the positive and negative electrodes from each other. Most preferably a nonwoven polypropylene sheet is employed as the separator since it has the desired degree of porosity and yet has a sufficient tortuous path to prevent carbonaceous fibers from - penetrating through it, thus preventing electrical shorting. The porous separators also beneficially act as stiffeners or supports for the electrodes.
Energy storage devices which are contained in fluid-tight housings are generally known in the art.
Such housings may be suitably employed in the present invention as long as the housing material is electrically non-conductive and impervious to gases and/or moisture (water or water vapor).
The materials found chemically compatible as a housing material include polyvinylchloride, polyethylene, poIypropylene, polytrifluoroethylene and relaked per-fluorinated polymers, instant set polymer (ISP), a rapidly solidifying reactive urethane mixture, the aramids, a metal clad with a non-conductive polymeric material such as an epoxy e.g. DER* 331 or with DERAKANE*, ZETABON* and/or glass or a metal oxide, fluoride or the *Trademark of The Dow Chemical Company '. 30,532-F -12 .
' ~2~:94~
like. Houslng materials found not to be suitable in the preferred propylene carbonate system include acrylic, polycarbonate and nylon. Acrylics craze and poly-carbonates both crazes and becomes extremely brittle, while nylon (except for aramides) is chemically reactive.
In addition to being compatible, a housing material must also offer an absolute barrier of less than 0.2 grams of H20/yr/ft2 (2.15 grams of H2O/yr/m2) against the transmission of water vapor from the external environment of the housing. No presently known thermo-plastic materials alone offers this absolute barrier against moisture at a thickness which would be useful for a battery housing. At present only metals, for example aluminum or mild s-teel, offer an absolute barrier against moisture at oil thicknesses. Aluminum foil having a thickness of greater than 0.0015 in.
(0.038 mm) has been shown to be essentially impervious to water vapor transmission. It has also been shown that when laminated to other materials, aluminum foil as thin as 0.00035 in. (0.009 mm) can provide adequate protection against water vapor transmission. Suitable housings made of metal-plastic lamina-te, CED-epoxy-coated metal (cathodic electro deposited~, or metal with an internal liner of plastic or glass presen-tly satisfies the requirements for both chemical compatability and moisture barrier ability. Most of the cells and batteries built to date have been tested in either a dry box having a H20 level of <5 ppm, a glass cell or a double walled housing with the space between the walls filled with an activated molecular sieve e.g. 5A zeolite.
::
~ 30,532-F -13-:; ' , -~23~g~
The electrolyte fluld preferably consists ofa non-conductive, chemically stable, non-aqueous solvent for ionizable salt or salts wherein the ionizable salt is dissolved in the solvent. One can employ as the solvent those compounds that are generally known in the art such as, for example, compounds having oxygen, sulfur, and/or nitrogen atoms bound to caxbon atoms in an electrochemically non-reactive state. Preferably, one can employ nitriles such as acetonitrile; amides such as dimethyl formamide; ethers, such as tetrahydrofuran;
sulfur compounds, such as dimethyl sulfite; and other compounds such as propylene carbonate. It is, of course, to be understood that the solvent itself may be ionizable under conditions of use sufficient to provide the necessary ions in the solvent. Thus, the ionizable salt must be at least partially soluble and ionizable either when it is dissolved and goes into solution into the solvent or upon liquification. While it is to be understood that slightly soluble salts are operable, it will be recognized that the rate of electrical charginy and discharging may be adversely affected by the low concentration of such salts in solution.
Ionizable salts which may be employed in the practice of the invention are those taught in the prior art and include salts of the more active metals, such asj for example, the alkali metal salts, preferably lithium, sodium or potassium, or mixtures thereof containing stable anions such as perchlorate (ClO~=), tetrafluoroborate (BF4=), hexafluoroarsenate (AsF6=), hexafluoroant1monate (SbF6=) or hexafluorophosphate (PF6=).
:
~ 30,532-F ~14-~29~
The electrolyte (solvent and salt) must be substantially water-free, -that is, it should contain less than 100 ppm of water, preferably less than 20 ppm of water and most preferably less than lO ppm of water.
Of course, the electrolyte can be made up having more than the desired amount of water and dryed, for example, over activated zeolite 5A molecular sieves. Such agents may also be combined in-to the finished battery to ensure that the low level water requirement ls maintained. The electrolyte should also be such as to permit ions (anions and cations) of the ionizable salt to move freely through the solvent as the electrical potential of charge and discharge move the ions to and from their respective poles (electrodes).
The electrode, when constructed as a cloth or sheet, includes an electron collector conductively associated with at least one of the edges of the carbonaceous fibers or sheet. The edge(s) is preferably further protected by a material to insulate the collector and to substantially protect the electron collector from contact with the fluid and its electrolyte ions.
The protective material must, of course, be unaffected by the fluid or the electrolyte ions.
The current collector intimately contacts the carbonaceous material of the electrode at least along one edge and preferably on all four edges thereof when the carbonaceous material is in the form of an assembly such as a planar cloth, sheet or felt. It is also ~nvisioned that the electrode may be constructed in other shapes such as in the form of a cylindrical or tubular bundle of fibers, threads or yarns in which the ends of the bundle are provided with a current collector.
It is also apparent that an electrode in the form of a 30,532-F -15-~3Zg~l' planar body of cloth, sheet or felt can be rolled up with a porous separator between the layers of the carbonaceous material, and with the opposed edges of the rolled up material, connected to a current collector.
While copper metal has been used as a current collector, any electro-conductive metal or alloy may be employed, such as, for example, silver, gold, platinum, cobalt, palladium, and alloys thereof. Likewise, while electrodeposition has been used in bonding a metal or metal alloy to the carbonaceous material, other coating techniques (including melt applications) or electroless deposition methods may be employed as long as the edges or ends of the electrode, including a majority of the fiber ends at the edges of the carbonaceous material are wetted by the metal to an extent sufficient to provide a substantially low-resistant electrical contact and current path.
Collectors made from a non-noble metal, such as copper, nickel, silver or alloys of such metals, must be protected from the electrolyte and therefore are preferably coated with a synthetic resinous material or an oxide, fluoride or the like which will not be attacked by the electrolyte or undergo any significant degradation at the operating conditions of a cell.
Electrodes of the present invention made from the electrically conductive carbonaceous material and its current collector can be employed as the positive electrode in a secondary energy storage device. No substantial damage to the electrode itself or the electrolyte, i.e., solvent and ioni~able salt, is observed when undergoing repeated charges at a capacity of greater than 150 coulombs per gram of ac-tive .
' 30,532-F -16-:~3'~
earbonaceous matexial, and deep diseharges at a depth of greater than 80 percent of the total capacity of the electrode at fast or slow rates of charge/discharge.
Alternatively, electrodes of the invention made from the electrically conductive carbonaceous material and its current collector can also be employed as both the positive and negative eleetrodes in an accumulator (secondary battery) wi-th similar benefieial operating eharaeteristics as hereinbefore deseribed.
A surfaee area of at least 0.5 square meters per gram and a low resistivity of less than 0.05 ohm~em of the earbonaeeous material employed for the eleetrode of the invention are desirable properties. Thus, a battery eonstrueted with the earbonaeeous material electrodes of the invention has an extremely low internal resistanee and a very high eorresponding eoulometrie effieieney whieh usually is greater than 80 pereent.
During the investigative period for the limits of the present invention it was found tha-t initial eurrent densities on eharge greater than 100 to 200 mA/in2 (15.5 to 31 mA/em ) can result in damage to the carbonaeeous material of th~e eleetrode.
The present invention will now be more fully explained in the following examples, with referenee to the aeeompanying drawings, in which:
Figure 1 is a graphical representation of the relation-ship between terminal vol-tage and discharge for a 0.9 ohm eell which is fully described in Example 4 hereinbelow;
Figure 2 is a graphical representa-tion of the relation-ship between terminal voltage and diseharge for a 0.7 ohm eell .1 .. , , ~, , ~ , : ~ - : ' ~3;~
which is fully described in Example 4 hereinbelow;
Figure 3 graphically illustrates the differences between the 0.9 ohm and 0.7 ohm cells;
Figure 4 graphically illustrates the maximum power density against the state of charge for a battery cell containing active carbonaceous ma-terial in accordance with the present invention; and Figure 5 graphically illustrates the high rate power discharge of the cell referred to in Figure 4 and in Example 4 hereinbelow.
A pair of electrodes each having an area of 11 in (71 cm2) were prepared from a Panex (Trade Mark) PWB-6 cloth (a cloth which had been heat treated at a temperature greater than 1000C
by the manufacturer which rendered this cloth electroconductive) purchased from Stackpole Fibers Industry Company. The cloth was - 17a -~" ~ "
;~
1;~3~4~
woven from a polyacrylonitrile (PAN) precursor in which the yarn was manufactured from non-continuous filaments (staple fibers) having an average length of about 2 inches (5 cm) and a diameter of 7 to 8 miGrometers and an aspect ratio of about 700:1. The cloth was heat treated by the manufacturer after weaving. The edges of the heat treated cloth were coated with copper by electroplating to provide a current collector. A wire was soldered to one end of the copper coated edges.
All four edges of each electrode (current collector and wire connector) were coated with an amine curable epoxy resin, DER (Trade Mark) 331, manufactured by The Dow Chemical Company, to insulate the metal from the corrosive effects of the electrolyte under the conditions of use.
The pair of electrodes were immersed in an electrolyte comprising a lS percent solution of LiCl04 in propylene carbonate contained in a polyvinylchloride (PVC) housing.
The electrodes were spaced less than 0~25 inch (0.6 cm) apart. The assembly of the electrodes into the housing was carried out in a dry bo~. The housing was sealed while in the dry box with the wires extending from the housing. The water content in the assembled housing was less than 10 ppm. The fibers had a Young's modulus of about 33,000,000 psi (230 GPa) and an area to weight ratio of 0.6 to 1.0 m2/g. The total electrical capacity of the active carbonaceous material of the electrode was determined to be about 250 coulombs/g.
The cell so-prepared was electrically charged at a ma~imum voltage of 5.3 volts with the current llmited from exceeding 35 milliamps per square inch (5.4 milliamps/cm2) electrode face area. The cell was electrically charged and discharged 1250 cycles over an 11 month period and exhibited a coulometric efficiency 30,532-F -18-.
:~ :
;. ~ -, , -~ .
~'- ' ,.
' .
~23~
of greater than 90 percent, conducted at a discharge capacity of greater -than 85 percent. The cell was then dismantled and the fibers from each of the cloth electrodes were examined under a microscope with lO00 power magnification. Insofar as measurable, the fibers had the same diameter as the fibers from the same lot which had not been used in the cell. The cell was reassembled and testing continued in the same manner as hereinbefore described. The cell has completed, thus
Accordingly, the carbonaceous material of an electrode having the physical properties hereinbefore described preferably should be capable of sustaining electrical discharge and recharge of more than 100 cycles at a discharge capacity of greater than 150 coulombs per gram of carbonaceous material in an electrode and at a coulometric efficiency of greater than 70% without any substantial irreversible change in dimensions (dimensional change of less than about 5%).
Usually, the carbonaceous material will be obtained by heating a precursor material to a temperature above 850C until electrically conductive. Carbonaceous precursor starting materials capable of forming the electrically conductive oriented carbonaceous material ; ~ portion of the electrode may be formed from pitch (petroleum or coal tar), polyacetylene, polyacrylonitrile, polyphenylene, SARAN (Trade Mark), and the like. The carbonaceous precursor starting material should have 30,532-F -8-.~,~
, ' `~! ~ ' , ' ,. ` "
`
, ' ' '':
~29~
some degree of skeletal orien-ta-tion, i.e., many of these materials either have substantial concentrations of oriented benzenoid structural moieties or moieties which are capable of conversion, on heating, to benzenoid or equivalent skeletal orientation at or near the surface because of the skeletal orientation of the starting material.
Exemplary of preferred carbonaceous precursor materials which exhibit such skeletal orientation on heating are assemblies of multi or monofilament strands or fibers prepared from petroleum pitch or polyacrylo-nitrile. Such multi or monofilament strands or fibers are readily converted into threads or yarns which can then be fabricated into a cloth-like product. One technigue for producing suitable monofilament fibers is disclosed in U.S. Patent No. 4,005,183 where the fibers are made into a yarn which is then woven into a cloth.
The cloth is then subjected to a temperature, usually above 1000C, sufficient to carbonize the cloth to make ~0 the carbonaceous material electrically conductive and so as to provide the material with the physical property characteristics hereinbefore described under paragraphs (1) through (6). Such a cloth, in con~unction with an electron collector, is particularly suitable for use as an electrode in the secondary electrical energy storage device of the present invention.
Advantageously, the carbonaceous precursor material is in the form of a continuous filament fiber, thread(s) constituted o continuous filament(s) or non-continuous fiber tow (yarn) which can be made into assemblies such as woven, non-woven, or knitted assemblies, or the staple fibers per se can be layered ~ 30,532-F -9-,. .
.
.
~:3Z~
to form a cloth, paper-like or felt-like planar member.
However, acceptable results are obtained when yarns made from short fibers, having a length of from l to lO
cm, are woven into a cloth-like product (provided such short fibers still have, when heat treated, the required physical properties hereinbefore mentioned under (1) through (6~). It is of course to be understood that while it is advantageous to form the precursor material, preferably in a stabilized state (such as is obtained by oxidation3, into the desired form (knit, woven or felt) prior to carbonization, such construction may be done after carbonization if the modulus is below about 55,000,000 psi (380 GPa) and preferably below about 39,000,000 psi (269 GPa) for machine fabrication. It is of course to be understood that the carbonaceous material may be formed from a film precursor.
The degree of carbonization and/or graphiti-zation does not appear to be a controlling factor in the performance of the material as an electrode element in an electrical storage device except tha-t it must be enough to render the material sufficiently electrically conductive and is also enough to provide the afore-mentioned physical and mechanical properties under the designated use conditions. Carbonaceous materials ; 25 having about 90 percent carbonization, are refexred to in the literature as partially carbonized. Carbonaceous materials having from 91 to 98 percent carbonization are referred to in the literature as a carbonized material, while materials having a carbonization of greater than 98 percent are referred to as graphitized.
; It has surprisingly been found that carbonaceous materials having a degree of carbonization, of from 90 to 99 percent, have failed as electrode materials unless 30,532-F -10-.
~23~
the carbonaceous material has the required dimensional stability during electrical charge and discharge cycling.
For example, ~PG graphite and GRAFOIL, while having the requisite degree of carbonization, electrical conduc-tivity and surface area, do not have the required physical properties of Young's Modulus and aspect ratio and thus have failed.
In accordance with the invention, a rechargable and polarity reversible electrical storage device can be prepared by aligning at least one pair of electrodes, made from the aforedescribed carbonaceous material and its associated electron collector (which are electrically conductive) in a housing. The housing has a non-conductive interior surface and is impervious to moisture. The electrodes are immersed in a non-aqueous (water being present in an amount of less than about 100 ppm) fluid contained in said housing. The fluid itself must be capable of forming, or contains dissolved therein, at least one ionizable metal salt. Each electrode is comprised of the carbonaceous heat-treated material, of the present invention, associated with an electron collector which is preferably insulated against contact uith the electrolyte fluid.
The secondary electrical energy storage device of the invention may be constructed without the polarity reversing capability by aligning the aforementioned electrically conductive carbonaceous fiber assembly, such as a cloth, and its electron collector as the positive electrode alternating with a negative electrode which may be constxucted of a metal, such as lithium, or a metal alloy and immersing the electrodes in a substantially non-aqueous fluid, which fluid itself is .
~ 3~,532-F -11--, capable of forming or which contains at least one ionizable soluble metal salt dissolved therein to provide electrolyte ions~
In the construction of a preferred embodiment of the secondary electrical energy storage device of the present invention, conventional porous separators of fiberglass, polymeric materials, or composites of polymeric materials, may ~e and are preferably employed to separate the positive and negative electrodes from each other. Most preferably a nonwoven polypropylene sheet is employed as the separator since it has the desired degree of porosity and yet has a sufficient tortuous path to prevent carbonaceous fibers from - penetrating through it, thus preventing electrical shorting. The porous separators also beneficially act as stiffeners or supports for the electrodes.
Energy storage devices which are contained in fluid-tight housings are generally known in the art.
Such housings may be suitably employed in the present invention as long as the housing material is electrically non-conductive and impervious to gases and/or moisture (water or water vapor).
The materials found chemically compatible as a housing material include polyvinylchloride, polyethylene, poIypropylene, polytrifluoroethylene and relaked per-fluorinated polymers, instant set polymer (ISP), a rapidly solidifying reactive urethane mixture, the aramids, a metal clad with a non-conductive polymeric material such as an epoxy e.g. DER* 331 or with DERAKANE*, ZETABON* and/or glass or a metal oxide, fluoride or the *Trademark of The Dow Chemical Company '. 30,532-F -12 .
' ~2~:94~
like. Houslng materials found not to be suitable in the preferred propylene carbonate system include acrylic, polycarbonate and nylon. Acrylics craze and poly-carbonates both crazes and becomes extremely brittle, while nylon (except for aramides) is chemically reactive.
In addition to being compatible, a housing material must also offer an absolute barrier of less than 0.2 grams of H20/yr/ft2 (2.15 grams of H2O/yr/m2) against the transmission of water vapor from the external environment of the housing. No presently known thermo-plastic materials alone offers this absolute barrier against moisture at a thickness which would be useful for a battery housing. At present only metals, for example aluminum or mild s-teel, offer an absolute barrier against moisture at oil thicknesses. Aluminum foil having a thickness of greater than 0.0015 in.
(0.038 mm) has been shown to be essentially impervious to water vapor transmission. It has also been shown that when laminated to other materials, aluminum foil as thin as 0.00035 in. (0.009 mm) can provide adequate protection against water vapor transmission. Suitable housings made of metal-plastic lamina-te, CED-epoxy-coated metal (cathodic electro deposited~, or metal with an internal liner of plastic or glass presen-tly satisfies the requirements for both chemical compatability and moisture barrier ability. Most of the cells and batteries built to date have been tested in either a dry box having a H20 level of <5 ppm, a glass cell or a double walled housing with the space between the walls filled with an activated molecular sieve e.g. 5A zeolite.
::
~ 30,532-F -13-:; ' , -~23~g~
The electrolyte fluld preferably consists ofa non-conductive, chemically stable, non-aqueous solvent for ionizable salt or salts wherein the ionizable salt is dissolved in the solvent. One can employ as the solvent those compounds that are generally known in the art such as, for example, compounds having oxygen, sulfur, and/or nitrogen atoms bound to caxbon atoms in an electrochemically non-reactive state. Preferably, one can employ nitriles such as acetonitrile; amides such as dimethyl formamide; ethers, such as tetrahydrofuran;
sulfur compounds, such as dimethyl sulfite; and other compounds such as propylene carbonate. It is, of course, to be understood that the solvent itself may be ionizable under conditions of use sufficient to provide the necessary ions in the solvent. Thus, the ionizable salt must be at least partially soluble and ionizable either when it is dissolved and goes into solution into the solvent or upon liquification. While it is to be understood that slightly soluble salts are operable, it will be recognized that the rate of electrical charginy and discharging may be adversely affected by the low concentration of such salts in solution.
Ionizable salts which may be employed in the practice of the invention are those taught in the prior art and include salts of the more active metals, such asj for example, the alkali metal salts, preferably lithium, sodium or potassium, or mixtures thereof containing stable anions such as perchlorate (ClO~=), tetrafluoroborate (BF4=), hexafluoroarsenate (AsF6=), hexafluoroant1monate (SbF6=) or hexafluorophosphate (PF6=).
:
~ 30,532-F ~14-~29~
The electrolyte (solvent and salt) must be substantially water-free, -that is, it should contain less than 100 ppm of water, preferably less than 20 ppm of water and most preferably less than lO ppm of water.
Of course, the electrolyte can be made up having more than the desired amount of water and dryed, for example, over activated zeolite 5A molecular sieves. Such agents may also be combined in-to the finished battery to ensure that the low level water requirement ls maintained. The electrolyte should also be such as to permit ions (anions and cations) of the ionizable salt to move freely through the solvent as the electrical potential of charge and discharge move the ions to and from their respective poles (electrodes).
The electrode, when constructed as a cloth or sheet, includes an electron collector conductively associated with at least one of the edges of the carbonaceous fibers or sheet. The edge(s) is preferably further protected by a material to insulate the collector and to substantially protect the electron collector from contact with the fluid and its electrolyte ions.
The protective material must, of course, be unaffected by the fluid or the electrolyte ions.
The current collector intimately contacts the carbonaceous material of the electrode at least along one edge and preferably on all four edges thereof when the carbonaceous material is in the form of an assembly such as a planar cloth, sheet or felt. It is also ~nvisioned that the electrode may be constructed in other shapes such as in the form of a cylindrical or tubular bundle of fibers, threads or yarns in which the ends of the bundle are provided with a current collector.
It is also apparent that an electrode in the form of a 30,532-F -15-~3Zg~l' planar body of cloth, sheet or felt can be rolled up with a porous separator between the layers of the carbonaceous material, and with the opposed edges of the rolled up material, connected to a current collector.
While copper metal has been used as a current collector, any electro-conductive metal or alloy may be employed, such as, for example, silver, gold, platinum, cobalt, palladium, and alloys thereof. Likewise, while electrodeposition has been used in bonding a metal or metal alloy to the carbonaceous material, other coating techniques (including melt applications) or electroless deposition methods may be employed as long as the edges or ends of the electrode, including a majority of the fiber ends at the edges of the carbonaceous material are wetted by the metal to an extent sufficient to provide a substantially low-resistant electrical contact and current path.
Collectors made from a non-noble metal, such as copper, nickel, silver or alloys of such metals, must be protected from the electrolyte and therefore are preferably coated with a synthetic resinous material or an oxide, fluoride or the like which will not be attacked by the electrolyte or undergo any significant degradation at the operating conditions of a cell.
Electrodes of the present invention made from the electrically conductive carbonaceous material and its current collector can be employed as the positive electrode in a secondary energy storage device. No substantial damage to the electrode itself or the electrolyte, i.e., solvent and ioni~able salt, is observed when undergoing repeated charges at a capacity of greater than 150 coulombs per gram of ac-tive .
' 30,532-F -16-:~3'~
earbonaceous matexial, and deep diseharges at a depth of greater than 80 percent of the total capacity of the electrode at fast or slow rates of charge/discharge.
Alternatively, electrodes of the invention made from the electrically conductive carbonaceous material and its current collector can also be employed as both the positive and negative eleetrodes in an accumulator (secondary battery) wi-th similar benefieial operating eharaeteristics as hereinbefore deseribed.
A surfaee area of at least 0.5 square meters per gram and a low resistivity of less than 0.05 ohm~em of the earbonaeeous material employed for the eleetrode of the invention are desirable properties. Thus, a battery eonstrueted with the earbonaeeous material electrodes of the invention has an extremely low internal resistanee and a very high eorresponding eoulometrie effieieney whieh usually is greater than 80 pereent.
During the investigative period for the limits of the present invention it was found tha-t initial eurrent densities on eharge greater than 100 to 200 mA/in2 (15.5 to 31 mA/em ) can result in damage to the carbonaeeous material of th~e eleetrode.
The present invention will now be more fully explained in the following examples, with referenee to the aeeompanying drawings, in which:
Figure 1 is a graphical representation of the relation-ship between terminal vol-tage and discharge for a 0.9 ohm eell which is fully described in Example 4 hereinbelow;
Figure 2 is a graphical representa-tion of the relation-ship between terminal voltage and diseharge for a 0.7 ohm eell .1 .. , , ~, , ~ , : ~ - : ' ~3;~
which is fully described in Example 4 hereinbelow;
Figure 3 graphically illustrates the differences between the 0.9 ohm and 0.7 ohm cells;
Figure 4 graphically illustrates the maximum power density against the state of charge for a battery cell containing active carbonaceous ma-terial in accordance with the present invention; and Figure 5 graphically illustrates the high rate power discharge of the cell referred to in Figure 4 and in Example 4 hereinbelow.
A pair of electrodes each having an area of 11 in (71 cm2) were prepared from a Panex (Trade Mark) PWB-6 cloth (a cloth which had been heat treated at a temperature greater than 1000C
by the manufacturer which rendered this cloth electroconductive) purchased from Stackpole Fibers Industry Company. The cloth was - 17a -~" ~ "
;~
1;~3~4~
woven from a polyacrylonitrile (PAN) precursor in which the yarn was manufactured from non-continuous filaments (staple fibers) having an average length of about 2 inches (5 cm) and a diameter of 7 to 8 miGrometers and an aspect ratio of about 700:1. The cloth was heat treated by the manufacturer after weaving. The edges of the heat treated cloth were coated with copper by electroplating to provide a current collector. A wire was soldered to one end of the copper coated edges.
All four edges of each electrode (current collector and wire connector) were coated with an amine curable epoxy resin, DER (Trade Mark) 331, manufactured by The Dow Chemical Company, to insulate the metal from the corrosive effects of the electrolyte under the conditions of use.
The pair of electrodes were immersed in an electrolyte comprising a lS percent solution of LiCl04 in propylene carbonate contained in a polyvinylchloride (PVC) housing.
The electrodes were spaced less than 0~25 inch (0.6 cm) apart. The assembly of the electrodes into the housing was carried out in a dry bo~. The housing was sealed while in the dry box with the wires extending from the housing. The water content in the assembled housing was less than 10 ppm. The fibers had a Young's modulus of about 33,000,000 psi (230 GPa) and an area to weight ratio of 0.6 to 1.0 m2/g. The total electrical capacity of the active carbonaceous material of the electrode was determined to be about 250 coulombs/g.
The cell so-prepared was electrically charged at a ma~imum voltage of 5.3 volts with the current llmited from exceeding 35 milliamps per square inch (5.4 milliamps/cm2) electrode face area. The cell was electrically charged and discharged 1250 cycles over an 11 month period and exhibited a coulometric efficiency 30,532-F -18-.
:~ :
;. ~ -, , -~ .
~'- ' ,.
' .
~23~
of greater than 90 percent, conducted at a discharge capacity of greater -than 85 percent. The cell was then dismantled and the fibers from each of the cloth electrodes were examined under a microscope with lO00 power magnification. Insofar as measurable, the fibers had the same diameter as the fibers from the same lot which had not been used in the cell. The cell was reassembled and testing continued in the same manner as hereinbefore described. The cell has completed, thus
10 far, over 2,800 charge and discharge cycles over an 23 month period without a reduction in coulometric efficiency, it still has a coulometric efficiency of greater than 90 percent.
E~AMPLE 2 Six electrodes similar to the electrodes of Example 1 were prepared and connected in a three cell unit such that each of the three pairs of the electrodes were sealed in separate polyethylene pockets (bags).
The electrodes were connected in series. The three cell unit was operated in the same manner as in Example 1 except that the voltage was about 16 volts. The initial open circuit voltage was about 13.5 volts.
After 228 electrical charge and discharge cycles, during which the dischaxge was cond~cted at a deep discharge of greater than 78 percent of total capacity, the cells were dismantled and the electrodes were removed from their pockets and the fibers examined for signs of deterioration, i.e., flaking and excessive swelling and shrinking of the fibers. The examination showed no detectable change in fiber diameter from fibers measured in the same lot of cloth that had not been~used to prepare the electrode o this Example.
Measurements were conducted with a laser interEerometer.
, . 30,532-F -19-~- , .
';
, ~i23~
Several planar sheets were cut from a cloth woven from yarn made ~rom an essentially continuous monofilament precursor fiber made from petroleum pitch.
The fibers were manufactured by The Union Carbide Company and sold under the Trade Name Thornel (Trade Mark). The precursor fiber tow yarn with an aspect ratio of abou-t 800:1 had been woven into a cloth and then heat treated at a temperature of greater than 2000C. The planar sheets each had a dimension of about 1 ft2 (930 cm2) in area. The fiber had a Young's modulus of 45,000,000 psi (315 GPa) and a surface area of about 1 m2/gm after heat treatment. The sheets were plated with copper metal along their four edges so that all fibers were electrically connected to form an electron collector frame. An insulated copper wire was attached to one edge of the collector near a corner by solder and the solder joint and copper collector was coated with DERAKANE* brand of a curable vinyl ester resin. Each pair of sheets were aligned parallel to each other with the soldered wires at opposite ends of the matching edges and separated by a foraminous, non-woven, fibrous, polypropylene composite sheet having a thickness of 5 mils (0.1 mm). A polyethylene pocket (bag~ of a size of about 1 ft2 (930 cm2) was employed as a cell container. Three cells were assembled in a dry bo~ by placing a pair of the carbon ~iber sheets and their separator into each of three pockets and filling each pocket with about 500 grams of an electrolyte of 15 weight percent solution of LiClO~ in propylene carbonate. The electrolyte level in the pocket *Trademark of The Dow Chemical Company , 30,532-F -20-.
' . ~ ".
; ' ,., .
: : " :
.
~Z3~9~
was determined to provide 21 grams of active fiber per electrode (the area of the electrode exposed to the electrolyte). The remainder of the carbon fibers of each electrode extended out of the solution or was covered by the Derakane (Trade Mark) resin/copper metal frame.
Assembly of the cells in a dry box maintained the water content at less than 20 ppm of electrolyte solution. Each pocket was sealed while in the dry box, in a manner to allow the soldered wire ends -to extend through the seal at opposite ends of the sealed edge.
The three cells so-prepared were placed in a clear plastic box and the wires connected in series. A
quantity of activitated zeolite 5A molecular sieves (to absorb moisture) was added over the top of the cells and the assembly was removed from the dry box. The end wires of the two end plates of the three cell series were connected to terminals extending through a cover or lid for the box and the cover ~uickly sealed to -the box.
The assembly was charged at a potential of 15 to 16 volts, and at a current of 1.8 to 2 amps, for 45 minutes. Thereafter the device was discharged through a 12 volt automobile headlight drawing an average current of from 2.0 t~ 2.5 amps. The device was discharged to 90 percent of its capacity in 30 minutes.
The electrical charge and discharge cycles were conducted over 850 times. The cell was then disassemhled and the fibers examined under a microscope at 1000 times magni-fication and showed no detectable signs of swelling or 30,532-F -21-':
:
.
~3Z~
deterioration due to flaking. The device was accepting an electrical charge and deep discharge at 90 percent of capacity for each cycle.
A PAN base (precursor fiber) cloth was obtained from R. K. Textile, Ltd., Heaton Moor, U.K. The cloth was sold under the trade name Panox (Trade Mark) and was a non-conductive carbon fiber with an aspect ratio of greater than 250:1 made into yarn and woven cloth and, reportedly, had not been heated to a temperature above 400C. The cloth was heat treated at a temperature of about 1000C for a time sufficient to make the cloth electroconductive. The heat treated cloth had a Youngs modulus of 23,000,000 psi (160 GPa~ and a surace area of about 1 m2/gm. Two samples of cloth each having a width of 2 inches (5 cm) on a side and an area of 4 in2 (26 cm2~ were cut from the heat treated cloth and the four edges of each cloth were plated with copper metal to form a current collector for the electrode. A wire was soldered to one corner o~ the current collector of each electrode. The solder and copper current collector were coated with a Derakane (Trade Mark) brand vinyl ester resin coating composition. A non-woven poly-propylene composite sheet, Celgard (Trade Mark) 5511, was positioned between the two electrodes and the electrodes were inserted into a plastic pocket (envelope). This assembly was placed in a dry box wherein the water content was maintained at less than 20 ppm of electrolyte solution. A 10 weight percent 30~ solution of LiCl04 in a propylene carbonate solution was used to fill the envelope until the two electrodes were submersed in the electrolyte solution. The wires from each electrode were connected to a double pole, . 30,532-F -22-''' :;:
.
~ ' , ~;~3;~
double throw switch, one terminal of which was connected -to an electrical voltage source of 5.3 volts. The other terminal was connected to an electrical resistance load of 10 ohms. The cell was deep discharged to greater than 80 percent of its total charge and operated in excess of 800 electrical charge and discharge cycles with a coulometric efficiency of greater than 80 percent.
The capacity of this cell was about 70 percent of that of the PAN example (Example 1) on a total electrode weight basis.
Cells constructed in accordance with the present invention have been found to have an internal resistance which is, on the average, less than 0.038 ohm/ft2 (0.41 ohm/m2) of electrode face area in a six electrode cell. This value, originally measured as less than 1 ohm, included the lead wires to the charging system having a length of about 6 meters. On measuring the resistance of the leads and then remeasuring the total resistance of the system from the charge, the resistance of the accumulator (secondary battery) proper was calculated to be 0.038 ohm/ft2 (0.41 ohm/m2).
A confirmation of the data of the above examples was carried out by a co-worker in a 2 electrode cell made from "~hornel" cloth, VCB-45 having a Youngs modulus of 45,000,000 psi (315 GPa), a surface area of 1 m2/g and an aspect ratio of greater than 10,000:1, in which each cloth had a dimension of 15.2 cm x 15.2 cm.
~opper edges were plated around all four edges of the cloths to form the current collector. The current 30 ; collector was then coated with DERAKANE (Trade Mark) 470-36. The current collector edges were about 2.6 cm wide, leaving active carbonaceous material areas of ~ .
3a ~ 532-F -23- -': ':
- ~ :
~329~1 about 10 cm x 10 cm. The 100 cm2 area of each electrode contained about 6 grams of carbon fiber.
The electrodes were separated by placing one electrode in a heat sealed bag of "Celgard" (Trade Mark) 511 microporous polypropylene film.
The assembly of electrodes and separator was placed in a polyethylene bag, the bag filled with a dry electrolyte of 15 percent by weight LiCl04 in propylene carbonate (about 100 cc) and the assembly squeezed between two plastic edge pressure plates which support the sides of the bag holding the electrolyte. The thickness of the DERAKANE-coated copper current collector kept the fibrous portion of the two electrodes from being pressed into minimal separation distance with each other. In later runs, a 10 cm x 10 cm spacer plate was inserted between the edge pressure plates to press the electrode-separator combination more tightly together. This lowered the cell resistance from about 0.9 ohm down to about 0.7 ohm.
Discharge data at various discharge rates were taken for two of the above described configurations of the cell. In one case (0.9 ohm cell) the electrode separation was limited by the epoxy coating on the current collector to approximately 4 mm. In the other case (0.7 ohm cells), the electrodes were forced together at the center with only the porous poly-propylene separator between them (less than 1 mm).
In the graph of Figure 1, the curves show the terminal voltage vs. the discharge, coulombs per gram of fiber, for the 0.9 ohm cell at several discharge :
30,532-F -24-: :
. . .
~3;~
-25~
rates ranging from 6 hours to 3/4 hour. These discharges correspond to a so-called first plateau (2 volt cutoff). If one assumes that the total capacity of the 1st plateau is 180 coulombs per gram to the 2 volt cutoff voltage, the values on the abscissa can be replaced with "% discharged"; with "180 coulombs/gm"
equivalent to '1100% discharged".
The total energy recovered at a 3 hour rate at constant load is almost the same as at the 6 hour rate.
At the fast 3/4 hour rate discharge, inefficiencies are generated and occur due to cell resistance and electrode polarization. The electrode current densities corresponding to these discharge rates are:
Ave. Current density2at Rate (hours) constant load (ma/cm ) 6 0.5 3 1.0 1.5 2.0 0.75 4.0 The "coulombs per gram of fiber" is based on the weight of the active carbonaceous material of one electrode only.
In Figure 2, the curves show the data for the 3 0.7 ohm cell. Obviously, more energy is available for the cell with the lower resistance. In Figure 3, the curves show a comparison of the two cells at the higher discharge rate (3/4 hr rate)~
A lithium metal reference electrode was inserted into the cell to determine which electrode was 30,532-F -25-~.~ p ~; ~
polarizing. The voltage drops between each electrode and the reference electrode were determined during charge and discharge and on opening the circuit.
On opening the circuit, the voltages between the negative electrode and the reference electrode were generally less than 100 mv and changed only slightly with time. The voltage, when measured between the positive electrode and the reference electrode, changed with time, decreasing after each charge and increasing after each discharge.
The maximum power capabilities of a battery cell at different stages of charge were determined by pulse discharging the cell at loads that gave terminal voltages of one-half of open circuit voltage. The "pulses" were 10 seconds long and the power was calculated as the average power over the 10 seconds.
The cell was first charged to 344 coulombs per gram of active carbonaceous material in one electrode.
This was taken as a 100% state of charge. Maximum current drawn from the 10 cm x 10 cm electrode cell at 100% state of charge was 2.5 to 3.0 amperes. Subsequent power determinations were made at levels of 247 coulombs per gram (72% charge) and 224 coulombs per gram (65%
charge). ~ shows the results.
Maximum power from this cell was about 0.48 watts per gram of fiber at 100% state of charge, dropping to about 0.31 ~atts per gram of fiber at 72% state of charge. The power capabilities drop rapidly after that since the voltage drops and polarization sets in. A
pulse discharge of lonqer than 10 seconds does not 30,532-F -26-' .
, :: .
~23~
,C, g ~r ~ S
ne~essarily reduce the final power a great deal. ~v~
shows the voltage trace of a 40 second maximum power rate discharge. After the lst 10 seconds, the voltage drop is small.
A three cell battery was constructed from twelve plates, four per cell, of Thornel brand fiber described in Example 3. Each plate had a dimension of approximately 12 in x 12 in (144 in2 or 930 cm2), and had been copper plated on each edge. The copper plating along the edges was coated with Derakane (Trade Mark~ brand of curable vinyl ester resin. The plates had an active area of about 132 in2 ~852 cm2). The four plates of each cell were assembled with a foraminous polypropylene scrim separator between each plate.
Pairs of plates in each cell were connected in parallel so that on charge/discharge the plates were alternately +, -, +, -. The four plates and their separators were contained in a polypropylene bag having a dimension of 20 from 13 in x 13 in (33 cm x 33 cm) which contained about 600 cc of an electrolyte solution of 15 percent by weight of LiCl04 in propylene carbonate. This electrolyte level in each bag was sufficient to provide about 37 grams of active fibers per electrode plate.
The battery was initially charged over a period of 1000 minutes to a capacity of 7.9 amp hours at a potential of 14-16 volts. The cell was then discharged over a 200 minute period through a 12 volt automobile headlight putting out an average capacity of 6.2 amp hours representing greater than 80 percent depth of discharge. Recharge was carried out over an 800 minute period. An average of coulometric efficiency 30,532-F -27-- .
. ~
:~ ' ;, ' , - ~ ; -. ~ ,; .
~3;~3~' of approximately 90% on charge discharge cycling was observed.
:
~:~ 30,532-F -28-:
, ~ .
' ~
-
E~AMPLE 2 Six electrodes similar to the electrodes of Example 1 were prepared and connected in a three cell unit such that each of the three pairs of the electrodes were sealed in separate polyethylene pockets (bags).
The electrodes were connected in series. The three cell unit was operated in the same manner as in Example 1 except that the voltage was about 16 volts. The initial open circuit voltage was about 13.5 volts.
After 228 electrical charge and discharge cycles, during which the dischaxge was cond~cted at a deep discharge of greater than 78 percent of total capacity, the cells were dismantled and the electrodes were removed from their pockets and the fibers examined for signs of deterioration, i.e., flaking and excessive swelling and shrinking of the fibers. The examination showed no detectable change in fiber diameter from fibers measured in the same lot of cloth that had not been~used to prepare the electrode o this Example.
Measurements were conducted with a laser interEerometer.
, . 30,532-F -19-~- , .
';
, ~i23~
Several planar sheets were cut from a cloth woven from yarn made ~rom an essentially continuous monofilament precursor fiber made from petroleum pitch.
The fibers were manufactured by The Union Carbide Company and sold under the Trade Name Thornel (Trade Mark). The precursor fiber tow yarn with an aspect ratio of abou-t 800:1 had been woven into a cloth and then heat treated at a temperature of greater than 2000C. The planar sheets each had a dimension of about 1 ft2 (930 cm2) in area. The fiber had a Young's modulus of 45,000,000 psi (315 GPa) and a surface area of about 1 m2/gm after heat treatment. The sheets were plated with copper metal along their four edges so that all fibers were electrically connected to form an electron collector frame. An insulated copper wire was attached to one edge of the collector near a corner by solder and the solder joint and copper collector was coated with DERAKANE* brand of a curable vinyl ester resin. Each pair of sheets were aligned parallel to each other with the soldered wires at opposite ends of the matching edges and separated by a foraminous, non-woven, fibrous, polypropylene composite sheet having a thickness of 5 mils (0.1 mm). A polyethylene pocket (bag~ of a size of about 1 ft2 (930 cm2) was employed as a cell container. Three cells were assembled in a dry bo~ by placing a pair of the carbon ~iber sheets and their separator into each of three pockets and filling each pocket with about 500 grams of an electrolyte of 15 weight percent solution of LiClO~ in propylene carbonate. The electrolyte level in the pocket *Trademark of The Dow Chemical Company , 30,532-F -20-.
' . ~ ".
; ' ,., .
: : " :
.
~Z3~9~
was determined to provide 21 grams of active fiber per electrode (the area of the electrode exposed to the electrolyte). The remainder of the carbon fibers of each electrode extended out of the solution or was covered by the Derakane (Trade Mark) resin/copper metal frame.
Assembly of the cells in a dry box maintained the water content at less than 20 ppm of electrolyte solution. Each pocket was sealed while in the dry box, in a manner to allow the soldered wire ends -to extend through the seal at opposite ends of the sealed edge.
The three cells so-prepared were placed in a clear plastic box and the wires connected in series. A
quantity of activitated zeolite 5A molecular sieves (to absorb moisture) was added over the top of the cells and the assembly was removed from the dry box. The end wires of the two end plates of the three cell series were connected to terminals extending through a cover or lid for the box and the cover ~uickly sealed to -the box.
The assembly was charged at a potential of 15 to 16 volts, and at a current of 1.8 to 2 amps, for 45 minutes. Thereafter the device was discharged through a 12 volt automobile headlight drawing an average current of from 2.0 t~ 2.5 amps. The device was discharged to 90 percent of its capacity in 30 minutes.
The electrical charge and discharge cycles were conducted over 850 times. The cell was then disassemhled and the fibers examined under a microscope at 1000 times magni-fication and showed no detectable signs of swelling or 30,532-F -21-':
:
.
~3Z~
deterioration due to flaking. The device was accepting an electrical charge and deep discharge at 90 percent of capacity for each cycle.
A PAN base (precursor fiber) cloth was obtained from R. K. Textile, Ltd., Heaton Moor, U.K. The cloth was sold under the trade name Panox (Trade Mark) and was a non-conductive carbon fiber with an aspect ratio of greater than 250:1 made into yarn and woven cloth and, reportedly, had not been heated to a temperature above 400C. The cloth was heat treated at a temperature of about 1000C for a time sufficient to make the cloth electroconductive. The heat treated cloth had a Youngs modulus of 23,000,000 psi (160 GPa~ and a surace area of about 1 m2/gm. Two samples of cloth each having a width of 2 inches (5 cm) on a side and an area of 4 in2 (26 cm2~ were cut from the heat treated cloth and the four edges of each cloth were plated with copper metal to form a current collector for the electrode. A wire was soldered to one corner o~ the current collector of each electrode. The solder and copper current collector were coated with a Derakane (Trade Mark) brand vinyl ester resin coating composition. A non-woven poly-propylene composite sheet, Celgard (Trade Mark) 5511, was positioned between the two electrodes and the electrodes were inserted into a plastic pocket (envelope). This assembly was placed in a dry box wherein the water content was maintained at less than 20 ppm of electrolyte solution. A 10 weight percent 30~ solution of LiCl04 in a propylene carbonate solution was used to fill the envelope until the two electrodes were submersed in the electrolyte solution. The wires from each electrode were connected to a double pole, . 30,532-F -22-''' :;:
.
~ ' , ~;~3;~
double throw switch, one terminal of which was connected -to an electrical voltage source of 5.3 volts. The other terminal was connected to an electrical resistance load of 10 ohms. The cell was deep discharged to greater than 80 percent of its total charge and operated in excess of 800 electrical charge and discharge cycles with a coulometric efficiency of greater than 80 percent.
The capacity of this cell was about 70 percent of that of the PAN example (Example 1) on a total electrode weight basis.
Cells constructed in accordance with the present invention have been found to have an internal resistance which is, on the average, less than 0.038 ohm/ft2 (0.41 ohm/m2) of electrode face area in a six electrode cell. This value, originally measured as less than 1 ohm, included the lead wires to the charging system having a length of about 6 meters. On measuring the resistance of the leads and then remeasuring the total resistance of the system from the charge, the resistance of the accumulator (secondary battery) proper was calculated to be 0.038 ohm/ft2 (0.41 ohm/m2).
A confirmation of the data of the above examples was carried out by a co-worker in a 2 electrode cell made from "~hornel" cloth, VCB-45 having a Youngs modulus of 45,000,000 psi (315 GPa), a surface area of 1 m2/g and an aspect ratio of greater than 10,000:1, in which each cloth had a dimension of 15.2 cm x 15.2 cm.
~opper edges were plated around all four edges of the cloths to form the current collector. The current 30 ; collector was then coated with DERAKANE (Trade Mark) 470-36. The current collector edges were about 2.6 cm wide, leaving active carbonaceous material areas of ~ .
3a ~ 532-F -23- -': ':
- ~ :
~329~1 about 10 cm x 10 cm. The 100 cm2 area of each electrode contained about 6 grams of carbon fiber.
The electrodes were separated by placing one electrode in a heat sealed bag of "Celgard" (Trade Mark) 511 microporous polypropylene film.
The assembly of electrodes and separator was placed in a polyethylene bag, the bag filled with a dry electrolyte of 15 percent by weight LiCl04 in propylene carbonate (about 100 cc) and the assembly squeezed between two plastic edge pressure plates which support the sides of the bag holding the electrolyte. The thickness of the DERAKANE-coated copper current collector kept the fibrous portion of the two electrodes from being pressed into minimal separation distance with each other. In later runs, a 10 cm x 10 cm spacer plate was inserted between the edge pressure plates to press the electrode-separator combination more tightly together. This lowered the cell resistance from about 0.9 ohm down to about 0.7 ohm.
Discharge data at various discharge rates were taken for two of the above described configurations of the cell. In one case (0.9 ohm cell) the electrode separation was limited by the epoxy coating on the current collector to approximately 4 mm. In the other case (0.7 ohm cells), the electrodes were forced together at the center with only the porous poly-propylene separator between them (less than 1 mm).
In the graph of Figure 1, the curves show the terminal voltage vs. the discharge, coulombs per gram of fiber, for the 0.9 ohm cell at several discharge :
30,532-F -24-: :
. . .
~3;~
-25~
rates ranging from 6 hours to 3/4 hour. These discharges correspond to a so-called first plateau (2 volt cutoff). If one assumes that the total capacity of the 1st plateau is 180 coulombs per gram to the 2 volt cutoff voltage, the values on the abscissa can be replaced with "% discharged"; with "180 coulombs/gm"
equivalent to '1100% discharged".
The total energy recovered at a 3 hour rate at constant load is almost the same as at the 6 hour rate.
At the fast 3/4 hour rate discharge, inefficiencies are generated and occur due to cell resistance and electrode polarization. The electrode current densities corresponding to these discharge rates are:
Ave. Current density2at Rate (hours) constant load (ma/cm ) 6 0.5 3 1.0 1.5 2.0 0.75 4.0 The "coulombs per gram of fiber" is based on the weight of the active carbonaceous material of one electrode only.
In Figure 2, the curves show the data for the 3 0.7 ohm cell. Obviously, more energy is available for the cell with the lower resistance. In Figure 3, the curves show a comparison of the two cells at the higher discharge rate (3/4 hr rate)~
A lithium metal reference electrode was inserted into the cell to determine which electrode was 30,532-F -25-~.~ p ~; ~
polarizing. The voltage drops between each electrode and the reference electrode were determined during charge and discharge and on opening the circuit.
On opening the circuit, the voltages between the negative electrode and the reference electrode were generally less than 100 mv and changed only slightly with time. The voltage, when measured between the positive electrode and the reference electrode, changed with time, decreasing after each charge and increasing after each discharge.
The maximum power capabilities of a battery cell at different stages of charge were determined by pulse discharging the cell at loads that gave terminal voltages of one-half of open circuit voltage. The "pulses" were 10 seconds long and the power was calculated as the average power over the 10 seconds.
The cell was first charged to 344 coulombs per gram of active carbonaceous material in one electrode.
This was taken as a 100% state of charge. Maximum current drawn from the 10 cm x 10 cm electrode cell at 100% state of charge was 2.5 to 3.0 amperes. Subsequent power determinations were made at levels of 247 coulombs per gram (72% charge) and 224 coulombs per gram (65%
charge). ~ shows the results.
Maximum power from this cell was about 0.48 watts per gram of fiber at 100% state of charge, dropping to about 0.31 ~atts per gram of fiber at 72% state of charge. The power capabilities drop rapidly after that since the voltage drops and polarization sets in. A
pulse discharge of lonqer than 10 seconds does not 30,532-F -26-' .
, :: .
~23~
,C, g ~r ~ S
ne~essarily reduce the final power a great deal. ~v~
shows the voltage trace of a 40 second maximum power rate discharge. After the lst 10 seconds, the voltage drop is small.
A three cell battery was constructed from twelve plates, four per cell, of Thornel brand fiber described in Example 3. Each plate had a dimension of approximately 12 in x 12 in (144 in2 or 930 cm2), and had been copper plated on each edge. The copper plating along the edges was coated with Derakane (Trade Mark~ brand of curable vinyl ester resin. The plates had an active area of about 132 in2 ~852 cm2). The four plates of each cell were assembled with a foraminous polypropylene scrim separator between each plate.
Pairs of plates in each cell were connected in parallel so that on charge/discharge the plates were alternately +, -, +, -. The four plates and their separators were contained in a polypropylene bag having a dimension of 20 from 13 in x 13 in (33 cm x 33 cm) which contained about 600 cc of an electrolyte solution of 15 percent by weight of LiCl04 in propylene carbonate. This electrolyte level in each bag was sufficient to provide about 37 grams of active fibers per electrode plate.
The battery was initially charged over a period of 1000 minutes to a capacity of 7.9 amp hours at a potential of 14-16 volts. The cell was then discharged over a 200 minute period through a 12 volt automobile headlight putting out an average capacity of 6.2 amp hours representing greater than 80 percent depth of discharge. Recharge was carried out over an 800 minute period. An average of coulometric efficiency 30,532-F -27-- .
. ~
:~ ' ;, ' , - ~ ; -. ~ ,; .
~3;~3~' of approximately 90% on charge discharge cycling was observed.
:
~:~ 30,532-F -28-:
, ~ .
' ~
-
Claims (22)
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:
1. An electrode for use in a secondary electrical energy storage device comprising an electrode body of an electrically conductive carbonaceous material, having a skeletal oriention, at least at or near the surface, and a current collector electrically associated therewith, wherein said carbonaceous material has a Youngs modulus of greater than 1,000,000 psi (6.9 GPa) and undergoes a physical dimensional change of less than 5% during repeated electrical charge and discharge cycling.
2. The electrode of Claim 1, wherein said carbonaceous material has a surface area of from 0.1 to 50 m2/g.
3. The electrode of Claim 1 or 2, wherein said carbonaceous material has a aspect ratio (l/d) or equivalent ratio of greater than 100 to 1.
4. The electrode of Claim 1, wherein said carbonaceous material has a self contained structural integrity in sizes of from 1 to greater than 144 in2 (6.45 cm2 to greater than 930 cm2).
.
30,532-F -29-
.
30,532-F -29-
5. The electrode of Claim 1, wherein said carbonaceous material is capable of sustaining more than 100 electrical discharge cycles of greater than 70% depth of discharge at greater than 70%
coulometric efficiency without any appreciable damage to the structural integrity of the material.
coulometric efficiency without any appreciable damage to the structural integrity of the material.
6. The electrode of Claim 1, wherein said carbonaceous material is in the form of a cloth, film, paper, paper-like, or felt-like planar sheet, or other assemblies.
7. The electrode of Claim 1, wherein said carbonaceous material is in the form of a cloth or felt-like cloth or sheet comprising an assembly of at least a yarn tow of continuous filaments or staple fibers having a length of from 1/2 to 4 inches (1 to 10 cm).
8. The electrode of Claim 1, wherein said carbonaceous material is a woven or knitted cloth made from an assembly of yarn tow of continuous filaments or staple fibers having a length of from 1/2 to 4 inches (1 to 10 cm).
9. The electrode of Claim 1, wherein said carbonaceous material is a cloth or felt-like cloth or sheet laid down from an assembly tow of continuous filaments or staple fibers.
10. The electrode of Claim 1, wherein said carbonaceous material assembly has a Youngs modulus of from 1,000,000 to 55,000,000 psi (6.9 GPa to 380 GPa), and wherein said carbonaceous material is derived from 30,532-F -30-a precursor material selected from a polyacrylonitrile or pitch.
11. The electrode of Claim 1, wherein said electron collector is an electrically conductive metal plated on at least one edge of said carbonaceous material, and wherein said plated edge is coated with a non-conductive, non-reactive protective material.
12. The electrode of Claim 10, wherein the carbonaceous material has a Youngs modulus of from 10,000,000 to 55,000,000 psi (69 GPa to 380 GPa).
13. The electrode of Claim 10, wherein the carbonaceous material has a Youngs modulus of from 20,000,000 to 45,000,000 psi (138 GPa to 311 GPa).
14. The electrode of Claim 1, wherein the carbonaceous material has a surface area of from 0.1 to 10 m2/g.
15. The electrode of Claim 1, wherein the carbonaceous material has a surface area of from 0.1 to 5 m2/g.
16. A secondary electrical energy storage device comprising a housing having an electrically non-conductive interior surface and a moisture impervious exterior surface or laminar body and having at least one cell positioned in said housing, each cell comprising a pair of electroconductive electrodes electrically insulated from contact with each other, said housing containing a substantially non-aqueous electrolyte, wherein at least one of the electrodes of 30, 532-F -31-each cell is an electrode as claimed in Claim 1,
17. The device of Claim 16, wherein the electrolyte comprises a non-conductive, chemically stable, non-aqueous solvent and an ionizable salt dissolved therein.
18. The device of Claim 17, wherein the electrolyte solvent is selected from compounds having oxygen, sulfur and/or nitrogen atoms bound to carbon atoms in an electrochemically, non-reactive state, and wherein said salt is an alkali metal salt.
19. The device of Claim 18, wherein the electrolyte solvent is propylene carbonate and the alkali metal salt is lithium perchlorate.
20. A secondary electrical energy storage device comprising a housing having an electrically non conductive interior surface and a moisture impervious outer surface or laminated body and having at least one cell positioned in said housing, each cell comprising a pair of electroconductive electrodes electrically insulated from contact with each other , said housing containing a substantially non-aqueous electrolyte, wherein each of the electrodes of each cell is an electrode as claimed in Claim 1.
21. A secondary electrical energy storage device comprising a housing having an electrically non-conductive interior surface and a moisture impervious outer surface or laminated body and having at least one cell positioned in said housing, each cell comprising 30,532-F -32-at least one pair of electroconductive electrodes electrically insulated from contact with each other, said housing containing a substantially non-aqueous electrolyte, wherein each of the electrodes of each cell is an electrode as claimed in Claim 1, and wherein each said electrode has the freedom of choice of polarity on recharge and the ability to be partially and/or fully reverse polarized without harm.
22. The device of Claim 20 having a maximum power density of over 0.31 watts per gram of active positive carbon electrode for a 40 second pulse period at full charge.
30,532-F -33-
30,532-F -33-
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US55823983A | 1983-12-05 | 1983-12-05 | |
| US558,239 | 1983-12-05 |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1232941A true CA1232941A (en) | 1988-02-16 |
Family
ID=24228739
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000469354A Expired CA1232941A (en) | 1983-12-05 | 1984-12-05 | Energy storage device |
Country Status (27)
| Country | Link |
|---|---|
| JP (1) | JPH0695458B2 (en) |
| KR (1) | KR890002673B1 (en) |
| AU (1) | AU556617B2 (en) |
| BE (1) | BE901217A (en) |
| BR (1) | BR8406257A (en) |
| CA (1) | CA1232941A (en) |
| CH (1) | CH663688A5 (en) |
| DD (1) | DD229539A5 (en) |
| DE (1) | DE3444188A1 (en) |
| DK (1) | DK579484A (en) |
| ES (2) | ES8609825A1 (en) |
| FI (1) | FI844807L (en) |
| FR (1) | FR2556138B1 (en) |
| GB (1) | GB2150741B (en) |
| GR (1) | GR81142B (en) |
| HU (1) | HU196271B (en) |
| IL (1) | IL73708A (en) |
| IN (1) | IN163543B (en) |
| IT (1) | IT1196354B (en) |
| LU (1) | LU85669A1 (en) |
| NL (1) | NL189635C (en) |
| NO (1) | NO844833L (en) |
| PH (1) | PH22325A (en) |
| PL (1) | PL250714A1 (en) |
| PT (1) | PT79603A (en) |
| SE (1) | SE460442B (en) |
| ZA (1) | ZA849438B (en) |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104094440A (en) * | 2011-11-24 | 2014-10-08 | 罗伯特·博世有限公司 | Housing for a galvanic element consisting of carbon fibre-reinforced polymer with a moisture-impermeable layer, galvanic cell, rechargeable battery and motor vehicle |
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| DE3588167T2 (en) * | 1984-06-12 | 1998-03-12 | Mitsubishi Chem Corp | Secondary batteries containing pseudo-graphite produced by pyrolysis as the electrode material |
| JPS617567A (en) * | 1984-06-22 | 1986-01-14 | Hitachi Ltd | Secondary battery and its manufacturing method |
| DE3680249D1 (en) * | 1985-05-10 | 1991-08-22 | Asahi Chemical Ind | SECONDARY BATTERY. |
| AU574580B2 (en) * | 1985-06-04 | 1988-07-07 | Sgl Technic Ltd. | Rechargeable secondary battery |
| DE102010010751A1 (en) * | 2010-03-09 | 2011-09-15 | Bernd Hildenbrand | Tubular electrode |
| WO2017068944A1 (en) | 2015-10-22 | 2017-04-27 | 住友電気工業株式会社 | Redox flow battery electrode, and redox flow battery |
| CN112964999B (en) * | 2021-03-18 | 2022-10-25 | 潍柴动力股份有限公司 | Battery state of charge acquisition method, device, equipment, medium and program product |
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1984
- 1984-12-03 IT IT23864/84A patent/IT1196354B/en active
- 1984-12-03 IL IL73708A patent/IL73708A/en not_active IP Right Cessation
- 1984-12-03 CH CH5714/84A patent/CH663688A5/en not_active IP Right Cessation
- 1984-12-03 IN IN946/MAS/84A patent/IN163543B/en unknown
- 1984-12-03 PT PT79603A patent/PT79603A/en unknown
- 1984-12-03 GR GR81142A patent/GR81142B/en unknown
- 1984-12-03 HU HU844467A patent/HU196271B/en unknown
- 1984-12-04 KR KR1019840007644A patent/KR890002673B1/en not_active Expired
- 1984-12-04 ES ES538241A patent/ES8609825A1/en not_active Expired
- 1984-12-04 NL NLAANVRAGE8403682,A patent/NL189635C/en not_active IP Right Cessation
- 1984-12-04 ZA ZA849438A patent/ZA849438B/en unknown
- 1984-12-04 NO NO844833A patent/NO844833L/en unknown
- 1984-12-04 PH PH31522A patent/PH22325A/en unknown
- 1984-12-04 DD DD84270260A patent/DD229539A5/en unknown
- 1984-12-04 DE DE19843444188 patent/DE3444188A1/en active Granted
- 1984-12-04 SE SE8406140A patent/SE460442B/en not_active IP Right Cessation
- 1984-12-04 PL PL25071484A patent/PL250714A1/en unknown
- 1984-12-05 DK DK579484A patent/DK579484A/en not_active Application Discontinuation
- 1984-12-05 BR BR8406257A patent/BR8406257A/en unknown
- 1984-12-05 CA CA000469354A patent/CA1232941A/en not_active Expired
- 1984-12-05 LU LU85669A patent/LU85669A1/en unknown
- 1984-12-05 BE BE0/214119A patent/BE901217A/en not_active IP Right Cessation
- 1984-12-05 AU AU36318/84A patent/AU556617B2/en not_active Ceased
- 1984-12-05 GB GB08430739A patent/GB2150741B/en not_active Expired
- 1984-12-05 FR FR8418537A patent/FR2556138B1/en not_active Expired - Lifetime
- 1984-12-05 JP JP59255833A patent/JPH0695458B2/en not_active Expired - Lifetime
- 1984-12-05 FI FI844807A patent/FI844807L/en not_active Application Discontinuation
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1986
- 1986-04-30 ES ES554551A patent/ES8800515A1/en not_active Expired
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN104094440A (en) * | 2011-11-24 | 2014-10-08 | 罗伯特·博世有限公司 | Housing for a galvanic element consisting of carbon fibre-reinforced polymer with a moisture-impermeable layer, galvanic cell, rechargeable battery and motor vehicle |
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