CN1828981A - Bipolar electrode of accumulator - Google Patents
Bipolar electrode of accumulator Download PDFInfo
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- CN1828981A CN1828981A CNA2006100391941A CN200610039194A CN1828981A CN 1828981 A CN1828981 A CN 1828981A CN A2006100391941 A CNA2006100391941 A CN A2006100391941A CN 200610039194 A CN200610039194 A CN 200610039194A CN 1828981 A CN1828981 A CN 1828981A
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- 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
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Abstract
Accumulator bipolar electrode features using current-carrying electrode as intermediate layer, anode and cathode respectively adhered on both sides, tabular table multihole anode pedestal set on anode outer side for supporting it in surface contact mode, thereon perforative hole to form anode hole submerged in anodic activity material, tabular table multihole cathode pedestal set on cathode outer side, thereon perforative hole to form cathode aperture submerged in cathode activity material, said anode hole and cathode aperture staggered arrangement, anode pedestal and cathode pedestal overlapping part to form two side isolation between active material and pole plate. Said invention has light in weight, corrosion resistant, long life or permanence, making portably and enough strength.
Description
Technical field:
The present invention relates to the bipolar electrode of electrochemical field, the bipolar electrode for lead-acid storage batteries of more specifically saying so.
Background technology:
Known bipolar electrode for lead-acid storage batteries, basic structure are as electrode, to guarantee enough structural strengths, corrosion resistance and battery sealing-performance with thicker metal material.Its shortcoming is that electrode weight is big, can't obtain high battery capacity.
The design of the alloy in lightweight of employing titanium alloy one class as electrode material arranged, but owing to cost height, resource-constrained are difficult to large-scale application.
Propose among the U.S.A 4542082 to improve bipolar electrode, adopt lighter polymeric material, adopt the metal material that approaches and perforation is arranged, be arranged in two sides of pedestal respectively as electrode as pedestal; In the hole of pedestal, the conducting element made from the conductive corrosion-resistant alloy is installed in sealing, and the end contacts with corresponding active material.
CN 1040708A patent has pointed out that above-mentioned use polymer non-conducting material is as pedestal, adopt two thin metal materials as electrode, as the existing shortcoming of the bipolar electrode of conducting element, and proposed to make the method that corrosion is slack-off, reduce electric leakage, prolong electrode life with the conduction pin.
In CN 1040708A patent, show, the shortcoming of the bipolar electrode of this class formation is difficult to thorough solution, can't reach low internal resistance, high power capacity, long-life advantage that the bipolar electrode battery should be realized, and a large amount of installations of conduction pin also will cause the increase of battery production cost, influence practicality.
Summary of the invention:
The present invention is for avoiding above-mentioned existing in prior technology weak point, provide a kind of with new construction realize in light weight, corrosion-resistant, the life-span long, it is easy to make and have the bipolar electrode for lead-acid storage batteries of sufficient intensity.
The technical scheme that technical solution problem of the present invention is adopted is:
Design feature of the present invention is: be the intermediate layer with the conductive electrode, anode and negative electrode difference paster are in its both sides, the outside at anode, the antianode outside forms support with the form of face contact tabular porous anode pedestal is set, run through on it the hole form anode hole, anode hole position anode is immersed in the active material of positive electrode; The outside at described negative electrode, the target outside forms support with the form of face contact tabular porous cathode pedestal is set, the hole of running through on it forms cathode aperture, cathode aperture position negative electrode is immersed in the active material of cathode, described anode hole and cathode aperture are staggered, the overlapping part that anode pedestal and negative electrode pedestal are arranged in it is staggered, the anode pedestal of described overlapping part makes anode and active material of positive electrode isolated, simultaneously, the negative electrode pedestal of overlapping part makes negative electrode and active material of cathode isolated, forms the two-sided isolation between active material and the battery lead plate.
Compared with the prior art, beneficial effect of the present invention is embodied in:
1, the present invention only need by thin metallic conduction electrode of a slice and corrosion-resistant pedestal can constitute in light weight, corrosion-resistant, the life-span long, it is easy to make, and the bipolar electrode for lead-acid storage batteries of sufficient intensity arranged.
2, the present invention is at anode hole and place, cathode aperture position; electrode only is one-sidedly to contact with active material; speed that electrode is corroded thereby reduction greatly; simultaneously, because the electrode in the electrode hole position has the protection that simultaneously is subjected to the pedestal resistant material, therefore; on this position; even localizing electrode's perforation that is corroded is arranged, the sealing of battery be can not destroy yet and leakage, electric leakage caused, but storage battery operate as normal still.
4, the version according to the present invention, when electrode material was very thin, the speed of electrode corrosion was decided by the electrode width rather than the thickness of electrode of lap between anode pedestal and the negative electrode pedestal in the areola.Such as thickness of electrode is 0.1mm, and the lap width is 0.5mm, suppose that more two-sided corrosion rate is identical, then to be etched to the time of perforation will be electrode to the electrode between anode hole 8 and the cathode aperture 7 by 2.5 times of single face corrosion failure time, and visible electrode life prolongs greatly.
5, the metallic conduction electrode among the present invention is laminar, and the battery pack of a plurality of bipolar electrode for lead-acid storage batteries composition tandem working is very easy.
Description of drawings:
Fig. 1 is a bipolar electrode configurations schematic diagram of the present invention.
Fig. 2 is the plane graph of bipolar electrode for lead-acid storage batteries of the present invention.
Fig. 3 forms the battery pack structure schematic diagram of tandem working for bipolar electrode of the present invention.
Fig. 4 is a cell electrode relative dimensions schematic diagram of the present invention.
Number in the figure: 1 negative electrode pedestal, 2 anode pedestals, 3 negative electrodes, 4 anodes, 5 active material of cathode, 6 active material of positive electrode, 7 cathode apertures, 8 anode holes, 9 conductive electrodes, 10 dividing plates, 11 negative electrode pedestal reinforcements, 12 anode pedestal reinforcements, 13 liquid filling holes, 14 steam vents, 15 cathode electrode lead-out terminals, 16 anode electrode lead-out terminals, 17 one pole cathode electrodes, 18 one pole anode electrodes, 19 splice plates.
Below the invention will be further described by embodiment:
Referring to Fig. 1, be the intermediate layer with conductive electrode 9, anode 4 and negative electrode 3 difference pasters are in its both sides; In the outside of anode 4, the antianode outside is set forms the tabular porous anode pedestal 2 that supports with the form of face contact, run through on it the hole form anode hole 8, anode hole 8 position anodes are immersed in the active material of positive electrode 6; In the outside of negative electrode 3, the tabular porous cathode pedestal 1 that the target outside is supported with the form formation of face contact is set, the hole of running through on it forms cathode aperture 7, and cathode aperture 7 position negative electrodes are immersed in the active material of cathode 5; Anode hole 8 and cathode aperture 7 are staggered, the overlapping part that anode pedestal and negative electrode pedestal are arranged in it is staggered, the anode pedestal of overlapping part makes anode 4 and active material of positive electrode 6 isolated, simultaneously, the negative electrode pedestal of overlapping part makes negative electrode 3 and active material of cathode 5 isolated, forms the two-sided isolation between active material and the battery lead plate.
Referring to Fig. 1, Fig. 3, in concrete the enforcement, conductive electrode 9, anode 4, negative electrode 3 in bipolar electrode are the bulk metal thin slices that can independently make, bipolar electrode for lead acid accumulator, its conductive electrode 9, anode 4, negative electrode 3 all can use pure lead material manufacturing, negative electrode pedestal 1 and anode pedestal 2 are corrosion resistant polymer pedestal, the hole that evenly distributes and run through on the pedestal, and the pedestal of this form can be made easily in a large number.
In this version, the anode 4 at position, electrode hole place and negative electrode 3 all only have one side to contact active material, thereby corrosion rate reduces greatly.Simultaneously, because the another side of electrode is subjected to the protection of corrosion-resistant polymer pedestal, therefore, even the perforation of part cell electrode material corrosion, but storage battery operate as normal still can not destroyed the sealing of battery and causes leakage, electric leakage.
In addition, between anode hole 8 and cathode aperture 7, one section anode pedestal and the staggered position of negative electrode pedestal are arranged, on this position, no matter be anode or anode, the two sides is all protected by corrosion-resistant polymer pedestal; When electrode material itself was very thin, the speed of electrode corrosion was by the electrode width rather than the thickness of electrode decision of alternating share in the areola.If thickness of electrode is 0.1mm, and the alternating share width is 0.5mm, if two-sided again corrosion rate is identical, then the time that pole plate is bored a hole because of being corroded between anode hole 8 and the cathode aperture 7 will be electrode by 2.5 times of single face corrosion failure time.Hence one can see that, and will prolong greatly the useful life of electrode.
Shown in Figure 2, in concrete the enforcement, with anode pedestal 2 is auxiliary pedestal, with negative electrode pedestal 1 is main pedestal, two ends as the negative electrode pedestal 1 of main pedestal, setting can form the insertion type splice plate 19 of serial connection between a plurality of bipolar electrodes, can realize the serial connection of a plurality of bipolar electrodes with the mutual intercalation between each bipolar electrode splice plate 19.
In order to guarantee the intensity of bipolar electrode for lead-acid storage batteries, anode pedestal reinforcement 12 and negative electrode pedestal reinforcement 11 are set respectively,
In concrete the enforcement, the big or small equidimension of the thickness of electrode of each several part, electrode hole can require to adjust according to difference, designs the long-life bipolar electrode in view of the above, and weight can't roll up.
According to present embodiment, can make bipolar electrode easily in a large number, the size of anode hole 8, cathode aperture 7 can be very little.With Fig. 4 is example; suppose on the battery lead plate with the electrode hole to be that the cell electrode size a * a at center is 2.5 * 2.5mm; each electrode hole size b * b is 2 * 2mm; anode hole 8 is that d is 2.5mm with the centre distance of adjacent cathode aperture 7; then the maximum planes of active material distance electrode bore edges conduction is 1.5mm apart from e; two-sided protected electrode width c is 0.5mm, and each cell electrode mean effort area is S1=2 * a * a=2 * 2.5 * 2.5=12.5mm on the battery lead plate
2When the gross thickness of conductive electrode 9, anode 4, negative electrode 3 was 0.1mm, the conductive cross-sectional area between anode hole 8 and the adjacent all around cathode aperture 7 was S2=(2+2+2+2) * 0.1=0.8mm
2When 1C discharges, electric current≤5mA that each cell electrode flow through, therefore the internal storage battery loss of voltage due to is very little, has embodied the superiority of the storage battery that bipolar electrode constituted.Equally, since cell electrode density height, each cell electrode balanced operation, the utilance height of active material, therefore storage battery can obtain very high capacity.
Shown in Figure 3, by a slice one pole cathode electrode 17, cathode electrode lead-out terminal 15, a slice one pole anode electrode 18, anode electrode lead-out terminal 16, and five bipolar electrodes, the 12V lead-acid batteries of composition tandem working.
Claims (2)
1, bipolar electrode for lead-acid storage batteries, it is characterized in that with conductive electrode (9) be the intermediate layer, anode (4) and negative electrode (3) difference paster are in its both sides, the outside in anode (4), the antianode outside forms support with the form of face contact tabular porous anode pedestal (2) is set, run through on it the hole form anode hole (8), anode hole (8) position anode is immersed in the active material of positive electrode (6); The outside in described negative electrode (3), the target outside forms support with the form of face contact tabular porous cathode pedestal (1) is set, the hole of running through on it forms cathode aperture (7), cathode aperture (7) position negative electrode is immersed in the active material of cathode (5), described anode hole (8) and cathode aperture (7) are staggered, the overlapping part that anode pedestal and negative electrode pedestal are arranged in it is staggered, the anode pedestal of described overlapping part makes anode (4) and active material of positive electrode (6) isolated, simultaneously, the negative electrode pedestal of overlapping part makes negative electrode (3) and active material of cathode (5) isolated, forms the two-sided isolation between active material and the battery lead plate.
2, bipolar electrode for lead-acid storage batteries according to claim 1 is characterized in that at the two ends of described tabular porous cathode pedestal (1), and setting can form the insertion type splice plate (19) of serial connection between a plurality of bipolar electrodes.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CNB2006100391941A CN100372154C (en) | 2006-03-23 | 2006-03-23 | Bipolar electrode of accumulator |
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CNB2006100391941A CN100372154C (en) | 2006-03-23 | 2006-03-23 | Bipolar electrode of accumulator |
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CN1828981A true CN1828981A (en) | 2006-09-06 |
CN100372154C CN100372154C (en) | 2008-02-27 |
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CNB2006100391941A Expired - Fee Related CN100372154C (en) | 2006-03-23 | 2006-03-23 | Bipolar electrode of accumulator |
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Family Cites Families (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US4542082A (en) * | 1982-02-08 | 1985-09-17 | California Institute Of Technology | Bipolar battery plate |
SU1644259A1 (en) * | 1988-07-18 | 1991-04-23 | Всесоюзный научно-исследовательский аккумуляторный институт | Bipolar electrode of electric cell |
US4892797A (en) * | 1989-03-10 | 1990-01-09 | Alupower, Inc. | Bipolar electrode and process for manufacturing same |
CN2881977Y (en) * | 2006-03-23 | 2007-03-21 | 何茂彬 | Double-pole electrode of battery |
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Granted publication date: 20080227 |