JP2005268061A - Lead storage cell - Google Patents
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- JP2005268061A JP2005268061A JP2004079376A JP2004079376A JP2005268061A JP 2005268061 A JP2005268061 A JP 2005268061A JP 2004079376 A JP2004079376 A JP 2004079376A JP 2004079376 A JP2004079376 A JP 2004079376A JP 2005268061 A JP2005268061 A JP 2005268061A
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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
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Abstract
Description
本発明は、特に、アイドルストップシステムや過充電防止システムなどの新システムが導入された自動車(新システム導入車)に適した、サイクル寿命に優れる鉛蓄電池に関する。 In particular, the present invention relates to a lead-acid battery excellent in cycle life, which is suitable for an automobile (new system introduction vehicle) in which a new system such as an idle stop system or an overcharge prevention system is introduced.
自動車用鉛蓄電池は、SLIバッテリーと呼ばれるように、主に、始動時のスタータ起動、照明、イグニッションに使用され、その他、高級車では100個以上搭載されるモーターの電源にも使用されているが、前記始動時のスタータ起動以外はエンジンが発電機を駆動して電力を供給するため、鉛蓄電池はさほど深い放電が行われることはなかった。また、前記鉛蓄電池は、発電機により充電されるため、満充電状態に置かれることが多く、過充電に強いことが求められていた。 Lead-acid batteries for automobiles, as called SLI batteries, are mainly used for starter start-up, lighting, and ignition at start-up, and are also used for the power supply of more than 100 motors in luxury cars. In addition to starting the starter at the time of starting, the engine drives the generator to supply power, so that the lead-acid battery was not discharged so deeply. Further, since the lead storage battery is charged by a generator, it is often placed in a fully charged state and has been required to be resistant to overcharging.
しかし、近年、自動車には、燃費改善や排出ガス削減が強く求められ、それに応じてアイドルストップシステムや過充電防止システムなどの新しいシステムが導入された。 However, in recent years, automobiles are strongly required to improve fuel consumption and exhaust emissions, and new systems such as an idle stop system and an overcharge prevention system have been introduced accordingly.
前記アイドルストップシステムは、信号などで自動車が停車したときにエンジンを停止し、発進時にはエンジンを速やかに始動して、主に排出ガスを削減するシステムである。
しかし、このシステムではエンジン停止時は、電力は、発電機からの供給が途絶えるため鉛蓄電池から供給され、そのため鉛蓄電池は従来に比較して深い放電が行われることになる。
The idling stop system is a system that mainly stops exhaust gas by stopping the engine when a vehicle is stopped by a signal or the like, and starting the engine quickly when starting.
However, in this system, when the engine is stopped, power is supplied from the lead storage battery because the supply from the generator is interrupted, and therefore the lead storage battery is deeply discharged as compared with the conventional case.
前記過充電防止システムは、過充電の手前で充電を終了して充電エネルギーを節減するシステムで、このシステムによれば、発電機の負荷、過充電に伴う電解液の減少、正極格子の腐食なども改善される。
しかし、このシステムでは、特に充電効率が低下した鉛蓄電池は、長期間、充電不足状態(所謂PSOC)で使用されることになる。
The overcharge prevention system is a system that terminates charging before overcharging and saves charging energy. According to this system, the load on the generator, the decrease in electrolyte due to overcharging, the corrosion of the positive grid, etc. Is also improved.
However, in this system, a lead storage battery whose charging efficiency has been lowered is used in a state of insufficient charging (so-called PSOC) for a long period of time.
このように、新システム導入車では、鉛蓄電池は深い放電と慢性的充電不足状態で使用されるため、電池寿命が著しく短くなった。特に充電不足状態での長期使用はサルフェーション(負極表面に硫酸鉛が密に晶出する現象)が起き易くなり、その結果負極の充電効率が低下して充電不足が更に進むという悪循環に陥ることになる。 In this way, in the new system introduction vehicle, the lead-acid battery is used in a deep discharge and chronic undercharged state, so the battery life is remarkably shortened. In particular, long-term use in an insufficiently charged state is likely to cause sulfation (a phenomenon in which lead sulfate is densely crystallized on the negative electrode surface), resulting in a vicious circle in which the charging efficiency of the negative electrode is reduced and the charging shortage further proceeds. Become.
サルフェーション防止策としては、負極板にカーボンを多量に添加し、前記カーボンを硫酸鉛の間隙に侵入させて導電パスを形成する方法(非特許文献1、特許文献1)が提案されている。 As a sulfation prevention measure, there has been proposed a method (Non-patent Document 1, Patent Document 1) in which a large amount of carbon is added to the negative electrode plate, and the carbon penetrates into the gap between the lead sulfates to form a conductive path.
しかしながら、前記カーボンを多量に添加する方法によっても、新システム導入車では、鉛蓄電池は十分な寿命改善効果が得られなかった。
このようなことから、本発明者等は新システム導入車における鉛蓄電池の寿命改善について研究し、Zn(亜鉛)およびAl(アルミニウム)を負極板や電解液に含有させた鉛蓄電池はサルフェーションが抑制され、新システム導入車に用いても十分長寿命が得られることを見出し、さらに研究を進めて本発明を完成させるに至った。
However, even with the method of adding a large amount of carbon, the lead-acid battery has not been able to obtain a sufficient life improvement effect in the new system introduction vehicle.
For this reason, the present inventors have studied the improvement of the life of lead-acid batteries in vehicles equipped with the new system. Lead-acid batteries containing Zn (zinc) and Al (aluminum) in the negative electrode plate or electrolyte solution have reduced sulfation. As a result, the inventors have found that a sufficiently long life can be obtained even when the vehicle is introduced into a new system, and have further advanced research to complete the present invention.
本発明の目的は新システム導入車に用いても長寿命の鉛蓄電池を提供することにある。 An object of the present invention is to provide a lead-acid battery having a long life even when used in a vehicle incorporating a new system.
請求項1記載発明は、負極板にZnが金属換算で0.005〜0.1重量部(負極活物質100重量部あたりの重量部)含有され、電解液にAlが硫酸塩換算で2〜50g/リットル含有されていることを特徴とする鉛蓄電池である。 According to the first aspect of the present invention, Zn is contained in the negative electrode plate in an amount of 0.005 to 0.1 parts by weight in terms of metal (parts by weight per 100 parts by weight of the negative electrode active material), and Al in the electrolyte is 2 to 2 in terms of sulfate. It is a lead storage battery characterized by containing 50 g / liter.
請求項2記載発明は、電解液にZnが金属換算で0.06〜1.4g/リットル含有され、Alが硫酸塩換算で2〜50g/リットル含有されていることを特徴とする鉛蓄電池である。 The invention according to claim 2 is a lead storage battery characterized in that the electrolyte contains 0.06 to 1.4 g / liter of Zn in terms of metal and 2 to 50 g / liter of Al in terms of sulfate. is there.
請求項3記載発明は、負極板にZnが金属換算で0.005〜0.1重量部(負極活物質100重量部あたりの重量部)含有され、電解液にZnが金属換算で0.06〜1.4g/リットル含有され、Alが硫酸塩換算で2〜50g/リットル含有されていることを特徴とする鉛蓄電池である。 According to a third aspect of the invention, the negative electrode plate contains 0.005 to 0.1 parts by weight of Zn in terms of metal (parts by weight per 100 parts by weight of the negative electrode active material), and the electrolyte contains 0.06 in terms of metal. A lead acid battery containing ˜1.4 g / liter and containing 2 to 50 g / liter of Al in terms of sulfate.
請求項4記載発明は、前記電解液が、20℃における比重が1.250〜1.320の硫酸水溶液であることを特徴とする請求項1乃至3のいずれかに記載の鉛蓄電池である。 A fourth aspect of the present invention is the lead acid battery according to any one of the first to third aspects, wherein the electrolytic solution is a sulfuric acid aqueous solution having a specific gravity at 20 ° C. of 1.250 to 1.320.
本発明の鉛蓄電池は、負極板または/および電解液にZnを適量含有させ、電解液にAlを適量含有させたものなので、前記ZnとAlの相乗効果によりサルフェーションが抑制され、深い放電と慢性的な充電不足状態で使用される新システム導入車に用いても十分な長寿命が得られる。
本発明の鉛蓄電池は、電解液に、20℃における比重が1.250〜1.320の硫酸水溶液を用いたとき、電池特性が良好になり、前記ZnとAlの相乗効果が安定して得られる。
Since the lead storage battery of the present invention contains an appropriate amount of Zn in the negative electrode plate and / or electrolyte and an appropriate amount of Al in the electrolyte, sulfation is suppressed by the synergistic effect of Zn and Al, deep discharge and chronic Even if it is used for a vehicle with a new system that is used in a state of insufficient charging, a sufficiently long life can be obtained.
When the sulfuric acid aqueous solution having a specific gravity of 1.250 to 1.320 at 20 ° C. is used as the electrolytic solution, the lead storage battery of the present invention has good battery characteristics and a stable synergistic effect of Zn and Al. It is done.
本発明の鉛蓄電池は、負極板または/および電解液に含有させたZnと、電解液に含有させたAlとの相乗効果により、負極板に晶出する硫酸鉛を微細化し或いは不安定にしてサルフェーションを抑制し、以て負極の充放電効率を改善したものである。 The lead storage battery of the present invention makes the lead sulfate crystallized on the negative electrode plate finer or unstable due to the synergistic effect of Zn contained in the negative electrode plate and / or electrolyte and Al contained in the electrolyte. It suppresses sulfation, thereby improving the charge / discharge efficiency of the negative electrode.
請求項1記載発明において、負極板に含有させるZnの量を金属換算で0.005〜0.1重量部(負極活物質100重量部あたりの重量部)に規定し、電解液に含有させるAlの量を硫酸塩換算で2〜50g/リットルに規定する理由は、いずれが前記下限値を下回ってもサルフェーションを十分抑制できず、いずれが前記上限値を上回ってもその効果が飽和してコスト的に不利になるためである。さらに過剰Znは水素過電圧の低下および自己放電の増大を招き、過剰Alは電解液の導電性低下(内部抵抗の増加)を招き、電池容量を低下させる。 In the first aspect of the present invention, the amount of Zn contained in the negative electrode plate is regulated to 0.005 to 0.1 parts by weight (parts by weight per 100 parts by weight of the negative electrode active material) in terms of metal, and Al contained in the electrolytic solution The reason for prescribing the amount of 2 to 50 g / liter in terms of sulfate is that the sulfation cannot be sufficiently suppressed no matter which is below the lower limit, and the effect is saturated and the cost is saturated even if any exceeds the upper limit. This is because it is disadvantageous. Further, excess Zn causes a decrease in hydrogen overvoltage and an increase in self-discharge, and excess Al causes a decrease in conductivity of the electrolyte (increase in internal resistance), resulting in a decrease in battery capacity.
請求項2記載発明において、電解液に含有させるZnの含有量を金属換算で0.06〜1.4g/リットルに規定する理由は、前記下限値を下回ってもサルフェーションを十分抑制できず、いずれが前記上限値を上回ってもその効果が飽和するためである。Alの含有量を硫酸塩換算で2〜50g/リットルに規定する理由は前記請求項1記載発明の場合と同じである。 In the invention according to claim 2, the reason why the content of Zn to be contained in the electrolytic solution is specified to be 0.06 to 1.4 g / liter in terms of metal is that sulfation cannot be sufficiently suppressed even if the content falls below the lower limit value. This is because even if the value exceeds the upper limit, the effect is saturated. The reason why the content of Al is regulated to 2 to 50 g / liter in terms of sulfate is the same as that of the first aspect of the present invention.
請求項3記載発明は、Znを負極板および電解液に適量含有させ、Alを電解液に適量含有させた鉛蓄電池であり、ZnおよびAlの含有量の規定理由は、前記請求項1、2記載発明の場合と同じである。 The invention described in claim 3 is a lead storage battery in which Zn is contained in an appropriate amount in the negative electrode plate and the electrolyte solution, and Al is contained in the electrolyte solution in an appropriate amount. Same as in the description invention.
本発明において、Alを電解液に含有させるには、予め電解液に溶解しておく方法の他、例えばAlの硫酸塩を負極板に含有させておき、電解液注入時に溶解させる方法も適用できる。 In the present invention, in order to contain Al in the electrolytic solution, in addition to the method of previously dissolving in the electrolytic solution, for example, a method of containing Al sulfate in the negative electrode plate and dissolving it at the time of injecting the electrolytic solution can be applied. .
本発明において、負極板に、必要に応じて、カーボン、リグニン、硫酸バリウムなどを含有させても良い。その量は、負極活物質100重量部あたり、それぞれ0.05〜3重量部、0.1〜1重量部、0.5〜5重量部が適当であり、前記下限値を下回ってはいずれもその効果が十分に得られず、上限値を上回って含有させてもその効果が飽和してコスト的に不利になる。 In the present invention, the negative electrode plate may contain carbon, lignin, barium sulfate or the like as necessary. The amount thereof is suitably 0.05 to 3 parts by weight, 0.1 to 1 part by weight, and 0.5 to 5 parts by weight, respectively, per 100 parts by weight of the negative electrode active material. The effect cannot be sufficiently obtained, and even if the content exceeds the upper limit, the effect is saturated and disadvantageous in cost.
本発明において、電解液には、20℃における比重が1.250〜1.320の硫酸水溶液を用いることが望ましい。その理由は、前記比重が下限値(1.250)未満では硫酸イオンの量が不足し、また上限値(1.320)を超えると充電効率が低下して、いずれの場合も容量不足を招く恐れがあり、さらに上限を超えるとガスが発生して電解液が減少し易くなるためである。 In the present invention, it is desirable to use an aqueous sulfuric acid solution having a specific gravity at 20 ° C. of 1.250 to 1.320 as the electrolytic solution. The reason is that when the specific gravity is less than the lower limit (1.250), the amount of sulfate ions is insufficient, and when the specific gravity exceeds the upper limit (1.320), the charging efficiency is lowered, and in any case, the capacity is insufficient. This is because if the upper limit is exceeded, gas is generated and the electrolytic solution tends to decrease.
本発明の鉛蓄電池は、電力貯蔵用、据え置きバックアップ用などとして用いても、前述と同様の長寿命効果が得られる。また本発明はシール型鉛蓄電池に適用しても長寿命効果が得られる。 Even if the lead storage battery of the present invention is used for power storage, stationary backup, etc., the same long life effect as described above can be obtained. Further, even if the present invention is applied to a sealed lead-acid battery, a long life effect can be obtained.
以下に、本発明を実施例により具体的に説明する。 Hereinafter, the present invention will be specifically described by way of examples.
所要数の未化成負極板と未化成正極板をポリエチレンセパレータを介在させて交互に積層し、この積層体の極板同士をCOS方式で溶接して極板群とし、これをポリプロピレン製電槽に入れ、前記電槽に蓋をヒートシールし、前記蓋の液口から比重1.10の硫酸水溶液に硫酸Alを種々の量溶かした電解液を注入し、次いで前記電槽を40℃の水槽に入れて理論容量の200%過充電して電槽化成を行い、次いで前記電解液の比重を1.250〜1.320の範囲に調整したのち、25℃、5時間率電流で完全充電して2Vの鉛蓄電池を製造した。この電池の5時間率容量は50Ahであった。前記硫酸Alの量は本発明規定値内で変化させた。 The required number of unformed negative electrode plates and unformed positive electrode plates are alternately laminated with a polyethylene separator interposed therebetween, and the electrode plates of this laminate are welded together by the COS method to form an electrode plate group. Put the lid into the battery case, heat-seal, inject an electrolyte containing various amounts of Al sulfate into a sulfuric acid aqueous solution with a specific gravity of 1.10 from the liquid port of the lid, and then put the battery case into a 40 ° C. water tank The battery is overcharged by 200% of the theoretical capacity to form a battery case, and then the specific gravity of the electrolyte is adjusted to the range of 1.250 to 1.320, and then fully charged at 25 ° C. for 5 hours with a current. A 2V lead acid battery was manufactured. The 5-hour rate capacity of this battery was 50 Ah. The amount of Al sulfate was changed within the specified range of the present invention.
前記未化成負極板は、ボールミル法で調整した酸化鉛に、平均粒径が1μmの酸化Zn粉末、比表面積が70m2/gのアセチレンブラック(カーボン)粉末および硫酸バリウム粉末をそれぞれ所定量加えて乾式混合し、得られた混合粉体にリグニンを溶かした水溶液を所定量加え、さらにイオン交換水を所定量加えながら混練して負極活物質ペーストを調製し、このペーストをPb−Ca合金の鋳造基板に充填し、これを温度40℃、湿度95%の雰囲気下で24時間熟成後、乾燥して作製した。 The unformed negative electrode plate is obtained by adding predetermined amounts of Zn oxide powder having an average particle diameter of 1 μm, acetylene black (carbon) powder and barium sulfate powder having a specific surface area of 70 m 2 / g to lead oxide prepared by a ball mill method. A predetermined amount of an aqueous solution in which lignin is dissolved is added to the obtained mixed powder, and a negative electrode active material paste is prepared by kneading while adding a predetermined amount of ion-exchanged water. This paste is cast into a Pb-Ca alloy. A substrate was filled, and this was aged in an atmosphere of a temperature of 40 ° C. and a humidity of 95% for 24 hours and then dried.
前記酸化Zn粉末の添加量は本発明規定値内で種々に変化させた。
前記カーボン粉末、硫酸バリウム粉末、リグニンは、それぞれ負極活物質100重量部あたり0.5、0.5、1.0重量部加えた。前記イオン交換水は、前記酸化鉛100重量部に対しておよそ10重量部加え、希硫酸は10重量部加えた。前記イオン交換水は負極活物質ペーストのカップ密度が約140g/2in3となるように加えた。
The added amount of the Zn oxide powder was variously changed within the specified value of the present invention.
The carbon powder, barium sulfate powder, and lignin were added at 0.5, 0.5, and 1.0 parts by weight per 100 parts by weight of the negative electrode active material, respectively. About 10 parts by weight of the ion-exchanged water was added to 100 parts by weight of the lead oxide, and 10 parts by weight of diluted sulfuric acid was added. The ion exchange water was added so that the cup density of the negative electrode active material paste was about 140 g / 2 in 3 .
前記未化成正極板は、酸化鉛100重量部にイオン交換水10重量部を加え、続いて比重1.27の希硫酸10重量部を加えながら混練してカップ密度140g/2in3の正極用ペーストを調整し、このペーストをPb−Ca合金の鋳造基板に充填し、次いで40℃、湿度95%の雰囲気で24時間熟成後、乾燥して作製した。 The unformed positive electrode plate was kneaded by adding 10 parts by weight of ion-exchanged water to 100 parts by weight of lead oxide, and subsequently adding 10 parts by weight of dilute sulfuric acid having a specific gravity of 1.27, and a paste for positive electrode having a cup density of 140 g / 2 in 3 The paste was filled in a Pb—Ca alloy cast substrate, then aged in an atmosphere of 40 ° C. and 95% humidity for 24 hours, and then dried.
得られた各々の鉛蓄電池について、25℃の温度で5時間率電流で完全充電後、同じ雰囲気温度で、[60A、60秒間の定電流放電]→[60A、60秒間、上限電圧2.33Vの定電流・定電圧充電]を1サイクルとする耐久加速試験を行い、放電時の電圧が1.6V/セルを下回った時点のサイクル数を寿命とした。サイクル寿命数が4900以上を合格とした。 For each of the obtained lead storage batteries, after being fully charged at a temperature of 25 ° C. at a current rate of 5 hours, at the same atmospheric temperature, [60 A, constant current discharge for 60 seconds] → [60 A, 60 seconds, upper limit voltage 2.33 V Endurance acceleration test with a constant current / constant voltage charge] as one cycle, and the number of cycles at the time when the voltage during discharge fell below 1.6 V / cell was defined as the life. A cycle life number of 4900 or more was considered acceptable.
実施例1において、前記比重1.10の硫酸水溶液に硫酸Alと硫酸Znを種々の量溶かした電解液を用い、前記酸化鉛に酸化Zn粉末を含有させなかった他は、実施例1と同じ方法により鉛蓄電池を製造し、実施例1と同じ方法によりサイクル寿命数を測定した。前記硫酸Zn量は本発明規定値内とした。 Example 1 is the same as Example 1 except that an electrolytic solution in which various amounts of Al sulfate and Zn sulfate are dissolved in the sulfuric acid aqueous solution having a specific gravity of 1.10 is used, and the lead oxide does not contain Zn oxide powder. A lead storage battery was manufactured by the method, and the cycle life number was measured by the same method as in Example 1. The amount of Zn sulfate was within the specified value of the present invention.
実施例1において、前記比重1.10の硫酸水溶液に硫酸Alと硫酸Znを種々の量溶かした他は、実施例1と同じ方法により鉛蓄電池を製造し、実施例1と同じ方法によりサイクル寿命数を測定した。前記硫酸Zn量は本発明規定値内とした。 In Example 1, a lead storage battery was manufactured by the same method as in Example 1 except that various amounts of Al sulfate and Zn sulfate were dissolved in the sulfuric acid aqueous solution having a specific gravity of 1.10. Number was measured. The amount of Zn sulfate was within the specified value of the present invention.
実施例1において、電解液の比重を1.240または1.330に調整した他は、実施例1と同じ方法により鉛蓄電池を製造し、実施例1と同じ方法によりサイクル寿命数を測定した。 In Example 1, except that the specific gravity of the electrolyte was adjusted to 1.240 or 1.330, a lead storage battery was manufactured by the same method as in Example 1, and the cycle life number was measured by the same method as in Example 1.
実施例2において、電解液の比重を1.240または1.330に調整した他は、実施例2と同じ方法により鉛蓄電池を製造し、実施例2と同じ方法によりサイクル寿命数を測定した。 In Example 2, the lead acid battery was manufactured by the same method as Example 2 except having adjusted the specific gravity of electrolyte solution to 1.240 or 1.330, and the cycle life number was measured by the same method as Example 2. FIG.
(比較例1)
実施例1において、ZnおよびAlの含有量を本発明規定値外とした他は、実施例1と同じ方法により鉛蓄電池を製造し、実施例1と同じ方法によりサイクル寿命数を測定した。
(Comparative Example 1)
In Example 1, a lead storage battery was manufactured by the same method as in Example 1 except that the contents of Zn and Al were outside the specified values of the present invention, and the cycle life number was measured by the same method as in Example 1.
(比較例2)
実施例2において、ZnおよびAlの含有量を本発明規定値外とした他は、実施例2と同じ方法により鉛蓄電池を製造し、実施例2と同じ方法によりサイクル寿命数を測定した。
(Comparative Example 2)
In Example 2, a lead storage battery was manufactured by the same method as in Example 2 except that the contents of Zn and Al were outside the specified values of the present invention, and the cycle life number was measured by the same method as in Example 2.
実施例1〜5および比較例1、2のサイクル寿命数を表1に示した。
表1にはサイクル寿命以外の電池特性も考慮した総合評価結果を併記した。
総合評価は、サイクル寿命が4900回以上で、かつ寿命以外の特性に全く問題ないものを極めて優れる(◎)、サイクル寿命が4900回以上だが、電池特性に若干問題のあるものを優れる(○)、サイクル寿命が4900回未満は劣る(×)として行った。
The cycle life numbers of Examples 1 to 5 and Comparative Examples 1 and 2 are shown in Table 1.
Table 1 also shows the comprehensive evaluation results considering battery characteristics other than the cycle life.
Comprehensive evaluation is very excellent when the cycle life is 4900 times or more and there is no problem in characteristics other than the life (◎), and the cycle life is 4900 times or more but excellent in battery characteristics slightly (○) The cycle life of less than 4900 times was evaluated as inferior (x).
表1から明らかなように、本発明例の実施例1〜5の鉛蓄電池はサイクル寿命数が4900回以上で、長寿命であった。これはZnおよびAlの相乗効果によりサルフェーションが抑制されたためである。
前記ZnとAlの相乗効果は、例えば、実施例1(本発明例)のNo.3と比較例1のNo.30、33を比較すると明白である。
なお、実施例4、5は電解液比重が1.250未満、または1.320を超えたため、電池容量の低下および電解液の減少の少なくとも一方が認められた。しかし、いずれも実用上差し支えない程度であった。
As is clear from Table 1, the lead storage batteries of Examples 1 to 5 of the inventive examples had a cycle life of 4900 times or more and a long life. This is because sulfation was suppressed by the synergistic effect of Zn and Al.
The synergistic effect of Zn and Al is, for example, No. 1 in Example 1 (example of the present invention). 3 and Comparative Example 1 It is clear when 30,33 are compared.
In Examples 4 and 5, since the specific gravity of the electrolyte was less than 1.250 or exceeded 1.320, at least one of a decrease in battery capacity and a decrease in electrolyte was observed. However, both were practically acceptable.
これに対し、比較例1、2の鉛蓄電池は、ZnまたはAlの含有量が本発明規定値外のためいずれもサルフェーションが抑制されず、サイクル寿命が低下した。またZnが多いNo.32、37は水素過電圧の低下および自己放電の増大が認められ、Alの多いNo.35、40は電池の内部抵抗が増大した。 On the other hand, in the lead acid batteries of Comparative Examples 1 and 2, since the Zn or Al content was outside the specified value of the present invention, sulfation was not suppressed and the cycle life was reduced. Further, No. with a large amount of Zn. Nos. 32 and 37 show a decrease in hydrogen overvoltage and an increase in self-discharge. In 35 and 40, the internal resistance of the battery increased.
本発明の鉛蓄電池(実施例1〜5)を新システム導入車に搭載したところ、電池寿命が従来の鉛蓄電池に較べて著しく優れることが確認された。 When the lead storage battery (Examples 1-5) of this invention was mounted in the new system introduction vehicle, it was confirmed that a battery life is remarkably excellent compared with the conventional lead storage battery.
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Cited By (3)
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JP2008243493A (en) * | 2007-03-26 | 2008-10-09 | Furukawa Battery Co Ltd:The | Lead acid storage battery |
JP2015005528A (en) * | 2014-09-05 | 2015-01-08 | 株式会社Gsユアサ | Lead storage battery |
JP2015144144A (en) * | 2015-05-12 | 2015-08-06 | 株式会社Gsユアサ | Lead acid battery |
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Publication number | Priority date | Publication date | Assignee | Title |
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JP2008243493A (en) * | 2007-03-26 | 2008-10-09 | Furukawa Battery Co Ltd:The | Lead acid storage battery |
JP2015005528A (en) * | 2014-09-05 | 2015-01-08 | 株式会社Gsユアサ | Lead storage battery |
JP2015144144A (en) * | 2015-05-12 | 2015-08-06 | 株式会社Gsユアサ | Lead acid battery |
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