JP6119368B2 - Prismatic secondary battery - Google Patents
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- JP6119368B2 JP6119368B2 JP2013068516A JP2013068516A JP6119368B2 JP 6119368 B2 JP6119368 B2 JP 6119368B2 JP 2013068516 A JP2013068516 A JP 2013068516A JP 2013068516 A JP2013068516 A JP 2013068516A JP 6119368 B2 JP6119368 B2 JP 6119368B2
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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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Description
本発明は、電流遮断機構を備えた角形二次電池に関する。 The present invention relates to a prismatic secondary battery having a current interruption mechanism.
電気自動車(EV)やハイブリッド電気自動車(HEV、PHEV)等の車載用の駆動電源に用いられる二次電池の開発が行われている。車載用の駆動電源には、高容量及び高出力特性が要求されるので、多数の電池を直列ないし並列に接続して使用される。これらの電池としては、スペース効率の点から角形二次電池が汎用されている。 Development of secondary batteries used for in-vehicle drive power sources such as electric vehicles (EV) and hybrid electric vehicles (HEV, PHEV) has been underway. Since an in-vehicle drive power supply requires high capacity and high output characteristics, a large number of batteries are connected in series or in parallel. As these batteries, square secondary batteries are widely used from the viewpoint of space efficiency.
このような用途に使用される電池は、特に非水電解質二次電池を用いる場合においては、携帯用の小型機器に用いる二次電池と比較して格段に高い安全性が要求されている。そのため、上記のような用途に使用される二次電池においては、下記特許文献1〜3に示されているように、電池外装体内の圧力が高まったときに内圧を開放するガス排出弁を設けるだけでなく、電極体と端子部材の間の電気的接続を切断する電流遮断機構が設けられている。 Batteries used for such applications are required to have significantly higher safety than secondary batteries used in portable small devices, particularly when nonaqueous electrolyte secondary batteries are used. Therefore, in the secondary battery used for the above-described applications, as shown in Patent Documents 1 to 3 below, a gas discharge valve that opens the internal pressure when the pressure in the battery exterior body increases is provided. In addition, a current interrupting mechanism for disconnecting the electrical connection between the electrode body and the terminal member is provided.
上記特許文献1〜3に開示されている発明によれば、電流遮断機構を備えているので安全性が高く、信頼性の高い角形二次電池が得られる。しかしながら、振動・落下等により電池に衝撃が加わった場合、電流遮断機構を構成する部品間の接続部等が損傷する虞がある。 According to the inventions disclosed in Patent Documents 1 to 3, since the current interrupting mechanism is provided, a prismatic secondary battery having high safety and high reliability can be obtained. However, when an impact is applied to the battery due to vibration, dropping, or the like, there is a risk of damage to the connection between the parts constituting the current interrupt mechanism.
本発明は、上述した従来技術の問題点を解決するものであり、電極体と端子部材の間に電流遮断機構を備えた角形二次電池において、振動・落下等により電池に衝撃が加わっても電流遮断機構が損傷し難く、信頼性の高い角形二次電池を提供することを目的とする。 The present invention solves the above-mentioned problems of the prior art, and in a square secondary battery having a current interrupting mechanism between an electrode body and a terminal member, even if an impact is applied to the battery due to vibration, dropping or the like. An object of the present invention is to provide a highly reliable prismatic secondary battery in which the current interrupt mechanism is not easily damaged.
本発明の一態様の角形二次電池は、
開口を有する外装体と、
貫通孔を有し、前記外装体の開口を封止する封口体と、
正極板及び負極板を有し、前記外装体内に収容された電極体と、
前記正極板又は前記負極板に電気的に接続された集電体と、
前記集電体に電気的に接続され、前記封口体の貫通孔を貫通する端子部材と、
筒状部を有し、前記集電体及び前記端子部材に電気的に接続された導電部材と、
前記導電部材に接続され、電池内部の圧力が予め定めた所定値よりも大きくなると変形する反転板と、
第1の貫通孔を有し、前記反転板と前記集電体との間に配置された第1絶縁部材と、
を有し、前記反転板の変形に伴い前記電極体と前記端子部材の間の電気的接続が切断される角形二次電池であって、
前記反転板と前記集電体とが前記第1の貫通孔に対応する位置で接続されており、
前記導電部材の筒状部の前記電極体側の端部は前記反転板によって封止されており、
前記第1絶縁部材は固定部を有し、前記固定部は、前記第1絶縁部材の本体部から前記封口体側に伸びる第1領域と、前記第1領域に形成され、前記第1領域から前記導電部材側に突出した第2領域を有し、
前記固定部により前記第1絶縁部材は前記導電部材に固定されており、
前記固定部を上方(前記封口体側)から見たとき、前記第2領域における先端部の幅は、前記第2領域の根本部の幅よりも小さい。
The prismatic secondary battery of one embodiment of the present invention is
An exterior body having an opening;
A sealing body having a through hole and sealing the opening of the exterior body;
An electrode body having a positive electrode plate and a negative electrode plate and housed in the outer package;
A current collector electrically connected to the positive electrode plate or the negative electrode plate;
A terminal member electrically connected to the current collector and penetrating the through hole of the sealing body;
A conductive member having a cylindrical portion and electrically connected to the current collector and the terminal member;
An inversion plate connected to the conductive member and deformed when the pressure inside the battery is greater than a predetermined value;
A first insulating member having a first through hole and disposed between the reversing plate and the current collector;
A prismatic secondary battery in which electrical connection between the electrode body and the terminal member is cut with deformation of the reversal plate,
The reversing plate and the current collector are connected at a position corresponding to the first through hole;
The end on the electrode body side of the cylindrical portion of the conductive member is sealed by the reversal plate,
The first insulating member has a fixing portion, and the fixing portion is formed in the first region extending from the main body portion of the first insulating member toward the sealing body, and from the first region to the first region. A second region protruding toward the conductive member;
The first insulating member is fixed to the conductive member by the fixing portion,
When the fixing portion is viewed from above (on the sealing body side) , the width of the tip portion in the second region is smaller than the width of the root portion of the second region.
本発明の一態様の角形二次電池においては、筒状部を有する導電部材、反転板、第1の絶縁部材、及び集電体により、圧力感応式電流遮断機構を形成している。すなわち、外装体内部の圧力が増大すると反転板が変形し、集電体と反転板との間の接続部、集電体に設けた薄肉部や溝部等の脆弱部、又は反転板に設けた薄肉部や溝部等の脆弱部が破断するため、電極体と端子部材の間の電気的接続が切断される。これにより、信頼性が高い角形二次電池が得られる。なお、電流遮断機構は、正極側及び負極側の少なくとも一方に設けられていればよい。 In the prismatic secondary battery of one embodiment of the present invention, a pressure-sensitive current interrupting mechanism is formed by a conductive member having a cylindrical portion, a reversing plate, a first insulating member, and a current collector. That is, when the pressure inside the exterior body increases, the reversing plate is deformed, and the connecting portion between the current collector and the reversing plate, the thin portion provided in the current collector, the weak portion such as the groove portion, or the reversing plate is provided. Since the fragile portion such as the thin portion or the groove portion is broken, the electrical connection between the electrode body and the terminal member is cut. Thereby, a prismatic secondary battery with high reliability is obtained. In addition, the electric current interruption mechanism should just be provided in at least one of the positive electrode side and the negative electrode side.
しかも、本発明の一態様の角形二次電池においては、第1絶縁部材と導電部材とが固定されているため、電池に振動・落下等により衝撃が加わっても、集電体と反転板との間の接続部にストレスが掛かり難くなっており、集電体との間の接続部等の破損が抑制される。これにより、角形二次電池に衝撃が加わっても、電流遮断機構が破損し難い、信頼性の高い角形二次電池が得られる。なお、導電部材における、第1絶縁部材の固定部と固定される位置は特に限定されない。導電部材における、第1絶縁部材の固定部と固定される位置は、導電部材の外面側とすることが好ましい。また、導電部材に設けたフランジ部又は凹部に第1絶縁部材の固定部を固定することが更に好ましい。 In addition, in the prismatic secondary battery according to one aspect of the present invention, the first insulating member and the conductive member are fixed. Therefore, even if an impact is applied to the battery due to vibration or dropping, the current collector and the reversing plate It is difficult to apply stress to the connection portion between the two, and damage to the connection portion between the current collector and the like is suppressed. Thereby, even if an impact is applied to the prismatic secondary battery, a highly reliable prismatic secondary battery is obtained in which the current interruption mechanism is not easily damaged. In addition, the position in the conductive member where the first insulating member is fixed is not particularly limited. The position where the first insulating member is fixed to the fixing portion of the conductive member is preferably the outer surface side of the conductive member. Further, it is more preferable to fix the fixing portion of the first insulating member to the flange portion or the concave portion provided in the conductive member.
ここで、電池の製造段階において第1絶縁部材を導電部材に固定する際、固定部が損傷
することを防止するため、慎重に第1絶縁部材を導電部材に装着する必要があった。このため、製造に時間が掛かり製造効率の低下に繋がる虞があった。そこで、発明者らが鋭意検討を行ったところ、固定部の形状を改良することにより、この課題を解決できることを見出した。本発明の一態様の角形二次電池においては、固定部の第2領域における先端部の幅を、第2領域の根本部の幅よりも小さくすることにより、製造効率を向上できる。さらに、第1絶縁部材を導電部材に装着する際に固定部に余計な負荷が掛からないため、固定部の耐久性の低下を防止できる。したがって、電池使用時においても電流遮断機構の損傷を防止できる。更に、固定部を側方から見たとき第2領域における先端部の厚みは、第2領域の根本部の厚みよりも小さいことが好ましい。
Here, when the first insulating member is fixed to the conductive member in the battery manufacturing stage, it is necessary to carefully attach the first insulating member to the conductive member in order to prevent the fixing portion from being damaged. For this reason, there is a possibility that the production takes time and the production efficiency is lowered. Therefore, the inventors have conducted intensive studies and found that this problem can be solved by improving the shape of the fixed portion. In the prismatic secondary battery of one embodiment of the present invention, the manufacturing efficiency can be improved by making the width of the tip portion in the second region of the fixed portion smaller than the width of the root portion of the second region. Furthermore, since an excessive load is not applied to the fixing portion when the first insulating member is attached to the conductive member, it is possible to prevent a decrease in durability of the fixing portion. Therefore, it is possible to prevent damage to the current interrupt mechanism even when the battery is used. Furthermore, it is preferable that the thickness of the tip portion in the second region is smaller than the thickness of the root portion of the second region when the fixing portion is viewed from the side .
なお、固定部は少なくとも一つ設けられていればよいが、複数個設けられていることがより好ましい。但し、固定部が複数個設けられている場合、複数個の固定部の全てにおいて、第2領域の先端部の幅が第2領域の根本部の幅よりも小さい必要はない。 Note that at least one fixing portion may be provided, but a plurality of fixing portions are more preferably provided. However, when a plurality of fixing portions are provided, the width of the tip portion of the second region need not be smaller than the width of the root portion of the second region in all of the plurality of fixing portions.
本発明の一態様の角形二次電池においては、前記第1絶縁部材は、前記集電体に固定されていることが好ましい。これにより、電池に衝撃が加わって電極体が外装体内で移動して集電体が引っ張られるように力が加わっても、集電体と反転板の接続部にストレスがより掛かり難くなり、更に信頼性の高い角形二次電池となる。 In the prismatic secondary battery of one embodiment of the present invention, it is preferable that the first insulating member is fixed to the current collector. As a result, even if an impact is applied to the battery and a force is applied so that the electrode body moves within the exterior body and the current collector is pulled, stress is less likely to be applied to the connection portion between the current collector and the inversion plate. A highly reliable prismatic secondary battery is obtained.
第1絶縁部材と集電体の固定方法は特に限定されない。特に好ましい構成としては、集電体に設けた開孔又は切り欠き部に、第1絶縁部材の突起部を接続する構成が好ましい。更に好ましくは、第1絶縁部材に設けた突起部を、集電体に設けた開孔又は切り欠き部に挿入し、突起部の先端を加熱ないし押圧して拡径させることにより第1絶縁部材と集電体を接続することが好ましい。他の構成としては、第1絶縁部材に爪部を設け、集電体の端部に爪部を引っ掛けるようにして固定することもできる。また、第1絶縁部材に集電体を
受け入れる集電体受け入れ部を設け、この集電体受け入れ部内に集電体を配置する構成とすることもできる。
The method for fixing the first insulating member and the current collector is not particularly limited. As a particularly preferable configuration, a configuration in which the protrusion of the first insulating member is connected to an opening or a notch provided in the current collector is preferable. More preferably, the first insulating member is formed by inserting a protrusion provided in the first insulating member into an opening or a notch provided in the current collector and heating or pressing the tip of the protrusion to expand the diameter. And the current collector are preferably connected. As another configuration, a claw portion may be provided on the first insulating member, and the claw portion may be fixed to the end portion of the current collector. Alternatively, the first insulating member may be provided with a current collector receiving portion that receives the current collector, and the current collector may be disposed in the current collector receiving portion.
本発明の一態様の角形二次電池においては、前記封口体と前記導電部材の間には第2絶縁部材が配置され、前記第1絶縁部材と前記第2絶縁部材は固定されていることが好ましい。これにより、電池に衝撃が加わっても集電体と反転板との間の接続部にストレスがより掛かり難くなり、更に信頼性の高い角形二次電池となる。第1絶縁部材と第2絶縁部材の固定方法は特に限定されない。好ましい構成としては、第2絶縁部材に突出部を有する接続部を設け、この突出部を第1絶縁部材の接続部に設けた貫通孔に嵌合する構成が考えられる。また、第1絶縁部材に突出部を有する接続部を設け、この突出部を第2絶縁部材に設けた接続部の貫通孔に嵌合することもできる。なお、本発明の一態様の角形二次電池において、端子部材及び筒状部を有する導電部材が封口体と電気的に接続されている構成とすることもできる。但し、端子部材及び筒状部を有する導電部材は、封口体と電気的に絶縁されていることが好ましい。 In the prismatic secondary battery of one embodiment of the present invention, a second insulating member is disposed between the sealing body and the conductive member, and the first insulating member and the second insulating member are fixed. preferable. As a result, even when an impact is applied to the battery, the connection between the current collector and the reversing plate is less likely to be stressed, and a more reliable prismatic secondary battery is obtained. The method for fixing the first insulating member and the second insulating member is not particularly limited. As a preferable configuration, a configuration in which a connection portion having a protruding portion is provided in the second insulating member, and the protruding portion is fitted into a through hole provided in the connecting portion of the first insulating member can be considered. Moreover, the connection part which has a protrusion part in the 1st insulating member can be provided, and this protrusion part can also be fitted in the through-hole of the connection part provided in the 2nd insulating member. Note that the prismatic secondary battery of one embodiment of the present invention can have a structure in which a terminal member and a conductive member having a cylindrical portion are electrically connected to a sealing body. However, it is preferable that the conductive member having the terminal member and the cylindrical portion is electrically insulated from the sealing body.
以下に本発明の一実施形態に係る角形二次電池を図面を参照しながら説明する。ただし、以下に示す角形二次電池は、本発明の一実施形態の技術思想を理解するための角形二次電池を例示するものであって、本発明をこの角形二次電池に特定することを意図するものではない。本発明の一実施形態は特許請求の範囲に示した技術思想を逸脱することなく種々の変更を行ったものにも均しく適用し得るものである。 Hereinafter, a rectangular secondary battery according to an embodiment of the present invention will be described with reference to the drawings. However, the prismatic secondary battery shown below exemplifies a prismatic secondary battery for understanding the technical idea of one embodiment of the present invention, and the present invention is specified as the prismatic secondary battery. Not intended. The embodiment of the present invention can be equally applied to a variety of modifications without departing from the technical idea shown in the claims.
[実施形態]
最初に、本実施形態の角形二次電池10を図1を用いて説明する。本実施形態の角形二次電池10は、正極板と負極板とがセパレータ(何れも図示省略)を介して巻回された偏平状の巻回電極体11を有している。正極板は、アルミニウム箔からなる正極芯体の両面に正極活物質合剤を塗布し、乾燥及び圧延した後、アルミニウム箔が一方の端部に長手方
向に沿って帯状に露出するようにスリットすることにより作製されている。また、負極板は、銅箔からなる負極芯体の両面に負極活物質合剤を塗布し、乾燥及び圧延した後、銅箔が一方の端部に長手方向に沿って帯状に露出するようにスリットすることによって作製されている。
[Embodiment]
First, the prismatic secondary battery 10 of the present embodiment will be described with reference to FIG. The square secondary battery 10 of this embodiment has a flat wound electrode body 11 in which a positive electrode plate and a negative electrode plate are wound via a separator (both not shown). The positive electrode plate is coated with a positive electrode active material mixture on both surfaces of a positive electrode core made of aluminum foil, dried and rolled, and then slit so that the aluminum foil is exposed in a strip shape along the longitudinal direction at one end. It is produced by. The negative electrode plate is coated with a negative electrode active material mixture on both sides of a negative electrode core made of copper foil, dried and rolled, and then the copper foil is exposed in a strip shape along the longitudinal direction at one end. It is made by slitting.
そして、上述のようにして得られた正極板及び負極板を、正極板の正極芯体露出部と負極板の負極芯体露出部とがそれぞれ対向する電極と重ならない領域を有するようにずらして、ポリエチレン製微多孔質セパレータを介して巻回することで、巻回軸方向の一方の端には複数枚重なった正極芯体露出部14を備え、他方の端には複数枚重なった負極芯体露出部15を備えた偏平状の巻回電極体11が作製されている。 Then, the positive electrode plate and the negative electrode plate obtained as described above are shifted so that the positive electrode core exposed portion of the positive electrode plate and the negative electrode core exposed portion of the negative electrode plate have regions that do not overlap with the opposing electrodes, respectively. By winding through a polyethylene microporous separator, a plurality of overlapping positive electrode core exposed portions 14 are provided at one end in the winding axis direction, and a plurality of overlapping negative electrode cores are provided at the other end. A flat wound electrode body 11 having a body exposed portion 15 is produced.
複数枚の正極芯体露出部14は積層されて正極集電体16を介して正極端子部材17に電気的に接続され、同じく複数枚の負極芯体露出部15は積層されて負極集電体18を介して負極端子部材19に電気的に接続されている。また、正極端子部材17、負極外部端子19はそれぞれ絶縁部材20、21を介して封口体13に固定されている。この実施形態の角形二次電池10では、正極板と正極端子部材17の間、あるいは負極板と負極端子部材19の間に感圧式の電流遮断機構が介在されているが、この電流遮断機構の具体的な構成については後述する。 The plurality of positive electrode core exposed portions 14 are laminated and electrically connected to the positive electrode terminal member 17 via the positive electrode current collector 16, and the plurality of negative electrode core exposed portions 15 are similarly laminated to be the negative electrode current collector. 18 is electrically connected to the negative electrode terminal member 19 through 18. Moreover, the positive electrode terminal member 17 and the negative electrode external terminal 19 are being fixed to the sealing body 13 via the insulating members 20 and 21, respectively. In the prismatic secondary battery 10 of this embodiment, a pressure-sensitive current interruption mechanism is interposed between the positive electrode plate and the positive electrode terminal member 17 or between the negative electrode plate and the negative electrode terminal member 19. A specific configuration will be described later.
実施形態の角形二次電池10は、上述のようにして作製された偏平状の巻回電極体11の封口体13側を除く周囲に絶縁性の樹脂シート23を介在させて角形の電池外装体12内に挿入した後、封口体13を電池外装体12の開口部にレーザ溶接し、その後、電解液注液孔22aから非水電解液を注液し、この電解液注液孔22aを密閉することにより作製されている。なお、封口体13には、電流遮断機構の作動圧よりも高いガス圧が加わったときに開放されるガス排出弁22bが設けられている。 The prismatic secondary battery 10 according to the embodiment has a prismatic battery outer body in which an insulating resin sheet 23 is interposed around the flat wound electrode body 11 manufactured as described above except for the sealing body 13 side. After being inserted into the sealing body 12, the sealing body 13 is laser welded to the opening of the battery exterior body 12, and then a nonaqueous electrolytic solution is injected from the electrolytic solution injection hole 22a, and the electrolytic solution injection hole 22a is sealed. It is made by doing. The sealing body 13 is provided with a gas discharge valve 22b that is opened when a gas pressure higher than the operating pressure of the current interrupt mechanism is applied.
なお、偏平状の巻回電極体11は、正極板側では、積層された複数枚の正極芯体露出部14が2分割されて、その間に2個の正極用中間導電部材24が挟まれている。同じく負極板側では、積層された複数枚の負極芯体露出部15が2分割されてその間に2個の負極用中間導電部材25が挟まれている。これらの2個の正極用中間導電部材24及び2個の負極用中間導電部材25はそれぞれ1個の樹脂材料からなる絶縁性中間部材24p、25pに保持されている。 In the flat wound electrode body 11, a plurality of stacked positive electrode core exposed portions 14 are divided into two on the positive electrode plate side, and two positive electrode intermediate conductive members 24 are sandwiched therebetween. Yes. Similarly, on the negative electrode plate side, a plurality of laminated negative electrode core exposed portions 15 are divided into two, and two negative electrode intermediate conductive members 25 are sandwiched therebetween. These two positive intermediate conductive members 24 and two negative intermediate conductive members 25 are respectively held by insulating intermediate members 24p and 25p made of one resin material.
そして、正極用中間導電部材24の両側に位置する正極芯体露出部14の最外側の両側の表面にはそれぞれ正極集電体16が配置されており、負極用中間導電部材25の両側に位置する負極芯体露出部15の最外側の両側の表面にはそれぞれ負極集電体18が配置されている。なお、正極用中間導電部材24は正極芯体と同じ材料であるアルミニウム製であり、負極用中間導電部材25は負極芯体と同じ材料である銅製である。これらの正極集電体16と正極芯体露出部14との間及び正極芯体露出部14と正極用中間導電部材24との間は共に抵抗溶接されており、また、負極集電体18と負極芯体露出部15との間及び負極芯体露出部15と負極用中間導電部材25との間は共に抵抗溶接によって接続されている。 The positive electrode current collectors 16 are arranged on the outermost surfaces on both sides of the positive electrode core exposed portion 14 located on both sides of the positive electrode intermediate conductive member 24, and are positioned on both sides of the negative electrode intermediate conductive member 25. Negative electrode current collectors 18 are arranged on the outermost surfaces of the negative electrode core exposed portion 15 to be respectively disposed. The positive electrode intermediate conductive member 24 is made of aluminum, which is the same material as the positive electrode core, and the negative electrode intermediate conductive member 25 is made of copper, which is the same material as the negative electrode core. Both the positive electrode current collector 16 and the positive electrode core exposed portion 14 and between the positive electrode core exposed portion 14 and the positive electrode intermediate conductive member 24 are resistance welded, and the negative electrode current collector 18 Both the negative electrode core exposed portion 15 and the negative electrode core exposed portion 15 and the negative electrode intermediate conductive member 25 are connected by resistance welding.
次に、電流遮断機構について説明するが、この電流遮断機構は、正極側にのみ設けても、負極側にのみ設けても、さらには正極側及び負極側の両方に設けてもよい。以下では正極側にのみ設けるものとして、図2〜図9を参照しながら説明する。 Next, the current interruption mechanism will be described. This current interruption mechanism may be provided only on the positive electrode side, only on the negative electrode side, or may be provided on both the positive electrode side and the negative electrode side. In the following, description will be made with reference to FIGS.
図1A〜図1Cに示すように、巻回電極体11の一方の側端面側に配置された複数の正極芯体露出部14には正極集電体16が接続されており、この正極集電体16は正極端子部材17に電気的に接続されている。この正極集電体16は、展開した状態の正面図であ
る図4A、同じく側面図である図4Bに示したように、封口体13と平行に配置される第1領域16aと、この第1領域16aから互いに反対方向に延在されており、破線部分(境界部16f)で折り曲げられて正極芯体露出部14に接続される一対の第2領域16bを有している。この正極集電体16は、厚さ0.8mmのアルミニウム板を打ち抜きに
より作製したものを使用している。
As shown in FIGS. 1A to 1C, a positive electrode current collector 16 is connected to the plurality of positive electrode core exposed portions 14 arranged on one side end face side of the wound electrode body 11, and this positive electrode current collector The body 16 is electrically connected to the positive terminal member 17. As shown in FIG. 4A, which is a front view in a developed state, and FIG. 4B, which is also a side view, the positive electrode current collector 16 includes a first region 16a disposed in parallel with the sealing body 13, and the first region 16a. It has a pair of 2nd area | regions 16b extended in the mutually opposite direction from the area | region 16a, bend | folded by the broken-line part (boundary part 16f), and is connected to the positive electrode core exposed part 14. FIG. The positive electrode current collector 16 is made by punching an aluminum plate having a thickness of 0.8 mm.
そして、正極集電体16の第1領域16aには、中央部に接続部形成用孔16cが形成され、この接続部形成用孔16cの中心を通り、封口体13の長辺方向に沿った中心線c上であって、接続部形成用孔16cの両側に第1開孔16g及び第2開孔16hがそれぞれ形成され、この中心線cに垂直な方向の両側には第3開孔16jが2箇所に形成されている。なお、ここでは、第1開孔16g及び第2開孔16hの径は同一とされ、2箇所の第3開孔16jの径は、共に同一であり、第1開孔16g及び第2開孔16hの径よりも小さく設定されている。また、第2領域16bには正極芯体露出部14の根元側と対向する側にリブ16dが形成されている。第1領域16aの接続部形成用孔16cの周囲部分は、環状に他の部分よりも厚さが薄くされた薄肉領域16eとされている。 In the first region 16 a of the positive electrode current collector 16, a connection part forming hole 16 c is formed at the center, passing through the center of the connection part forming hole 16 c, and along the long side direction of the sealing body 13. A first opening 16g and a second opening 16h are formed on the center line c on both sides of the connecting portion forming hole 16c, and third openings 16j are formed on both sides in a direction perpendicular to the center line c. Are formed in two places. Here, the diameters of the first opening 16g and the second opening 16h are the same, and the diameters of the two third openings 16j are the same, and the first opening 16g and the second opening 16h are the same. It is set smaller than the diameter of 16h. In the second region 16b, a rib 16d is formed on the side facing the base side of the positive electrode core exposed portion 14. A peripheral portion of the connection region forming hole 16c in the first region 16a is a thin region 16e that is annularly thinner than other portions.
正極端子部材17は、図2及び図3に示したように、筒状部17aを備え、内部に貫通孔17bが形成されている。そして、正極端子部材17の筒状部17aは、ガスケット等の第3絶縁部材20a、封口体13及び第2絶縁部材20b及び筒状部32aを有する導電部材32にそれぞれ形成された孔内に挿入され、その先端部17cがカシメられて互いに一体に固定されている。ここで、第2絶縁部材20bは、封口体13と導電部材32の間に配置される。なお、導電部材32は、電極体11側に筒状部32aが形成されており、封口体13側は内径が狭められて正極端子部材17の筒状部17aが挿入される開孔32bを形成している。そして、正極端子部材17の筒状部17aの先端部17cは導電部材32の開孔32bの近傍でカシメられており、正極端子部材17の筒状部17aの先端部17cと導電部材32の接続部はレーザ溶接されている。これにより、正極端子部材17は、第3絶縁部材20a及び第2絶縁部材20bによって封口体13とは電気的に絶縁された状態で、導電部材32と電気的に接続された状態となっている。なお、第3絶縁部材20aと第2絶縁部材20bとを一体物とすることもできる。 As shown in FIGS. 2 and 3, the positive electrode terminal member 17 includes a cylindrical portion 17a, and a through hole 17b is formed therein. And the cylindrical part 17a of the positive electrode terminal member 17 is inserted in the holes formed in the third insulating member 20a such as a gasket, the sealing body 13, the second insulating member 20b, and the conductive member 32 having the cylindrical part 32a, respectively. The tip portion 17c is caulked and fixed integrally with each other. Here, the second insulating member 20 b is disposed between the sealing body 13 and the conductive member 32. The conductive member 32 has a cylindrical portion 32a formed on the electrode body 11 side, and the sealing body 13 side has an inner diameter narrowed to form an opening 32b into which the cylindrical portion 17a of the positive electrode terminal member 17 is inserted. doing. The distal end portion 17 c of the cylindrical portion 17 a of the positive electrode terminal member 17 is crimped in the vicinity of the opening 32 b of the conductive member 32, and the connection between the distal end portion 17 c of the cylindrical portion 17 a of the positive electrode terminal member 17 and the conductive member 32 is performed. The part is laser welded. Thereby, the positive electrode terminal member 17 is in a state of being electrically connected to the conductive member 32 while being electrically insulated from the sealing body 13 by the third insulating member 20a and the second insulating member 20b. . Note that the third insulating member 20a and the second insulating member 20b may be integrated.
また、導電部材32の筒状部32aの電極体11側の先端にはフランジ部32cが形成されており、このフランジ部32cの内面側には反転板33の周囲が気密に溶接されて封止されている。反転板33は、周囲から中心側に向かって電極体11側に僅かに突出する形状、すなわち、封口体13とは傾斜した配置関係となる形状とされている。この反転板33は、アルミニウム等の導電性材料で形成されており、電池外装体12内の圧力が高くなると電池の外部側に向かって変形する弁の機能を有するものである。そして、反転板33の中心部には、正極集電体16の第1領域16aが当接され、第1領域16aに形成されている薄肉領域16eの接続部形成用孔16cの内壁部分と反転板33の表面とが複数箇所においてレーザ溶接されている。 Further, a flange portion 32c is formed at the tip of the cylindrical portion 32a of the conductive member 32 on the electrode body 11 side, and the periphery of the reversing plate 33 is hermetically welded and sealed to the inner surface side of the flange portion 32c. Has been. The inversion plate 33 has a shape that slightly protrudes toward the electrode body 11 from the periphery toward the center side, that is, a shape that is in an inclined relationship with the sealing body 13. The reversing plate 33 is made of a conductive material such as aluminum, and has a function of a valve that deforms toward the outside of the battery when the pressure in the battery outer body 12 increases. Then, the first region 16a of the positive electrode current collector 16 is brought into contact with the center portion of the reversing plate 33, and is inverted from the inner wall portion of the connection portion forming hole 16c of the thin region 16e formed in the first region 16a. The surface of the plate 33 is laser welded at a plurality of locations.
なお、正極集電体16の第1領域16aと反転板33との間には、第1の貫通孔34aを有する樹脂材料からなる第1絶縁部材34が配置されている。この第1の貫通孔34aと対応する位置において正極集電体16の第1領域16aと反転板33が接続されている。
ここで、正極集電体16と反転板33の接続部の構成としては、第1の貫通孔34aの内部で正極集電体16と反転板33が接続されてもよい。また、反転板33の一部が第1の貫通孔34aを貫通し、第1絶縁部材34よりも電極体11側で反転板33と正極集電体16が接続されてもよい。あるいは、正極集電体16の一部が第1の貫通孔34aを貫通し、第1絶縁部材34よりも封口体13側で反転板33と正極集電体16とが接続されていてもよい。
A first insulating member 34 made of a resin material having a first through hole 34 a is disposed between the first region 16 a of the positive electrode current collector 16 and the reversing plate 33. The first region 16a of the positive electrode current collector 16 and the reversing plate 33 are connected at a position corresponding to the first through hole 34a.
Here, as a configuration of a connection portion between the positive electrode current collector 16 and the reversal plate 33, the positive electrode current collector 16 and the reversal plate 33 may be connected inside the first through hole 34a. Further, a part of the reversing plate 33 may pass through the first through hole 34 a, and the reversing plate 33 and the positive electrode current collector 16 may be connected to the electrode body 11 side with respect to the first insulating member 34. Alternatively, a part of the positive electrode current collector 16 may pass through the first through hole 34 a, and the reversing plate 33 and the positive electrode current collector 16 may be connected to the sealing body 13 side with respect to the first insulating member 34. .
第1絶縁部材34の第1の貫通孔34aの周囲には、正極集電体16の第1領域16aの第1開孔16gに対応する位置に第1突起部34bが、第2開孔16hに対応する位置に第2突起部34cが、第3開孔16jに対応する位置に第3突起部34dが、それぞれ形成されている。 Around the first through hole 34a of the first insulating member 34, a first protrusion 34b is provided at a position corresponding to the first opening 16g of the first region 16a of the positive electrode current collector 16, and the second opening 16h. The second protrusion 34c is formed at a position corresponding to the third protrusion 34c, and the third protrusion 34d is formed at a position corresponding to the third opening 16j.
第1絶縁部材34の第1〜3突起部34b〜34dをそれぞれ正極集電体16の第1領域16aに形成された第1〜3開孔16g〜16j内に挿入し、第1〜3突起部34b〜34dの先端部を加熱し拡径することにより第1絶縁部材34と正極集電体16の第1領域16aが互いに固定されている。そのため、第1絶縁部材34の第1〜3突起部34b〜34dはそれぞれに形成された拡径部によって正極集電体16の第1領域16aに形成された第1〜3開孔16g〜16jから抜け止めされた状態となり、第1絶縁部材34と正極集電体の第1領域16aとは強固に接続された状態となっている。これらの正極集電体16の第1領域16aに形成された第1〜3開孔16g〜16jと第1絶縁部材34の第1〜3突起部34b〜34dとによって、第1固定部30a〜第3固定部30cが形成されている。なお、第1絶縁部材34と第2絶縁部材20bとを係合により固定することが好ましい。固定方法は特に限定されないが、ここではラッチ固定により第1絶縁部材34と第2絶縁部材20bとを固定している。 The first to third protrusions 34b to 34d of the first insulating member 34 are inserted into the first to third openings 16g to 16j formed in the first region 16a of the positive electrode current collector 16, respectively. The first insulating member 34 and the first region 16a of the positive electrode current collector 16 are fixed to each other by heating and expanding the diameter of the tip portions of the portions 34b to 34d. Therefore, the first to third projections 34b to 34d of the first insulating member 34 are first to third openings 16g to 16j formed in the first region 16a of the positive electrode current collector 16 by the enlarged diameter portions formed respectively. Thus, the first insulating member 34 and the first region 16a of the positive electrode current collector are firmly connected to each other. The first fixing portions 30a to 30d are formed by the first to third openings 16g to 16j formed in the first region 16a of the positive electrode current collector 16 and the first to third protrusions 34b to 34d of the first insulating member 34. A third fixing portion 30c is formed. In addition, it is preferable to fix the 1st insulating member 34 and the 2nd insulating member 20b by engagement. The fixing method is not particularly limited, but here, the first insulating member 34 and the second insulating member 20b are fixed by latch fixing.
正極芯体露出部14は、正極集電体16の第2領域16b、正極集電体16の第1領域16a、反転板33及び導電部材32を介して正極外部端子17と電気的に接続されている。また、ここでは、導電部材32の筒状部32a、反転板33、第1絶縁部材34及び正極集電体16の第1領域16aに形成された薄肉領域16eによって本実施形態の電流遮断機構35が形成されている。すなわち、反転板33は、電池外装体12内の圧力が増加すると正極端子部材17の貫通孔17b側に膨れるようになっており、反転板33の中央部には正極集電体16の第1領域16aの薄肉領域16eが溶接されているため、電池外装体12内の圧力が所定値を超えると正極集電体16の第1領域16aが薄肉領域16eの部分で破断するので、反転板33と正極集電体16の第1領域16aとの間の電気的接続が切断されるようになっている。 The positive electrode core exposed portion 14 is electrically connected to the positive electrode external terminal 17 via the second region 16 b of the positive electrode current collector 16, the first region 16 a of the positive electrode current collector 16, the reverse plate 33, and the conductive member 32. ing. Further, here, the current blocking mechanism 35 of the present embodiment is formed by the cylindrical portion 32 a of the conductive member 32, the reversing plate 33, the first insulating member 34, and the thin region 16 e formed in the first region 16 a of the positive electrode current collector 16. Is formed. That is, the reversing plate 33 swells toward the through hole 17b side of the positive electrode terminal member 17 when the pressure in the battery outer package 12 increases, and the first plate of the positive electrode current collector 16 is located at the center of the reversing plate 33. Since the thin region 16e of the region 16a is welded, the first region 16a of the positive electrode current collector 16 breaks at the thin region 16e when the pressure in the battery outer package 12 exceeds a predetermined value. And the first region 16a of the positive electrode current collector 16 are disconnected from each other.
なお、ここでは、第1領域16aの接続部形成用孔16cの周囲部分に環状に他の部分よりも厚さが薄くされた薄肉領域16eを形成した例を示したが、薄肉領域16eに接続部形成用孔16cを囲むように環状の溝を設けることがより好ましい。この溝は、環状に間欠的に形成してもよい。また、第1領域16aの接続部形成用孔16cの周囲部分の厚さを他の部分と同じ厚さとして、環状ないし環状に間欠的に溝を形成することによって薄肉領域16eを形成してもよい。なお、薄肉領域16e及び溝は必須の構成ではなく、薄肉領域16e及び溝を設けずに反転板33と正極集電体16の接続強度を調節し、反転板33が変形した場合に反転板33と正極集電体16の接続が切断されるようにしてもよい。 Here, an example is shown in which the thin region 16e having a smaller thickness than the other portions is formed around the connection portion forming hole 16c in the first region 16a. However, the thin region 16e is connected to the thin region 16e. It is more preferable to provide an annular groove so as to surround the part forming hole 16c. You may form this groove | channel intermittently cyclically | annularly. Alternatively, the thin region 16e may be formed by intermittently forming a groove in an annular or annular manner with the thickness of the peripheral portion of the connection region forming hole 16c in the first region 16a being the same as that of other portions. Good. Note that the thin region 16e and the groove are not indispensable configurations, and the connection strength between the reverse plate 33 and the positive electrode current collector 16 is adjusted without providing the thin region 16e and the groove. And the positive electrode current collector 16 may be disconnected.
正極端子部材17の貫通孔17bは、電流遮断機構35を構成する反転板33の周囲が導電部材32の筒状部32aに気密に溶接されているか否かの試験に用いられる。また、反転板33と集電体16を接続する際、電池外部側から貫通孔17bを通じて導電部材32の筒状部32aの内部に窒素ガスや空気等の気体を送り込み反転板33を集電体16に押し当てた状態で集電体16と溶接することができる。このような方法で、反転板33と集電体16を溶接すると、溶接接続部を安定的に形成できると共に、電流遮断機構の作動圧をより安定させることができる。 The through hole 17 b of the positive electrode terminal member 17 is used for a test of whether or not the periphery of the reversing plate 33 constituting the current interrupting mechanism 35 is air-tightly welded to the cylindrical portion 32 a of the conductive member 32. Further, when connecting the reversing plate 33 and the current collector 16, a gas such as nitrogen gas or air is fed into the cylindrical portion 32 a of the conductive member 32 from the outside of the battery through the through-hole 17 b, thereby connecting the reversing plate 33 to the current collector. It can be welded to the current collector 16 while being pressed against the current collector 16. When the reversing plate 33 and the current collector 16 are welded by such a method, the weld connection portion can be stably formed and the operating pressure of the current interrupt mechanism can be further stabilized.
なお、電解液の注液時や洗浄時に電解液や洗浄水が貫通孔17b内に侵入することを防ぐため、上記の工程の後封止することが好ましい。そこで、実施形態の角形二次電池10
では、正極端子部材17に形成された貫通孔17bは、ゴム製の端子栓36によって封止されている。この端子栓36は、上端部に頭部36aと、下端部に突出部36bと、係止部36cと、連結部36dと、を備えている。端子栓36の頭部36aの表面には、アルミニウム製の金属板37が設けられている。なお、貫通孔17bを封止する方法としては、金属板を貫通孔17bの周囲に溶接接続するようにしてもよい。
In order to prevent the electrolytic solution and the washing water from entering the through-hole 17b at the time of injecting or washing the electrolytic solution, it is preferable to seal after the above-described step. Therefore, the prismatic secondary battery 10 of the embodiment.
Then, the through-hole 17b formed in the positive electrode terminal member 17 is sealed with a rubber terminal plug 36. The terminal plug 36 includes a head portion 36a at an upper end portion, a protruding portion 36b at a lower end portion, a locking portion 36c, and a connecting portion 36d. An aluminum metal plate 37 is provided on the surface of the head 36 a of the terminal plug 36. As a method of sealing the through hole 17b, a metal plate may be welded and connected around the through hole 17b.
次に、実施形態の角形二次電池10に用いる第1絶縁部材34の具体的構成について、図5〜図9を用いて説明する。図5に示すように、第1絶縁部材34には第1の貫通孔34aが形成されており、この第1の貫通孔34aと対応する位置で反転板33と集電体16が接続される。第1絶縁部材34の上面には、図5A及び図5Dに示すように、複数、ここでは4つの固定部34fが第1の貫通孔34aを囲むように形成されている。図6に示すように、この固定部34fが導電性部材32のフランジ部32cの外面側に当接するようにして、第1絶縁部材34が導電性部材32に装着される。また、第1絶縁部材34の上面において第1絶縁部材34の周縁にはリブ34eが形成されている。このリブ34eにより、第1絶縁部材34の変形が抑制される。更に、固定部34fと第1絶縁部材34の周縁のリブ34eの間に、リブ34mが設けられていることが好ましい。 Next, the specific structure of the 1st insulating member 34 used for the square secondary battery 10 of embodiment is demonstrated using FIGS. As shown in FIG. 5, a first through hole 34a is formed in the first insulating member 34, and the reversing plate 33 and the current collector 16 are connected at a position corresponding to the first through hole 34a. . On the upper surface of the first insulating member 34, as shown in FIGS. 5A and 5D, a plurality of, here, four fixing portions 34f are formed so as to surround the first through hole 34a. As shown in FIG. 6, the first insulating member 34 is attached to the conductive member 32 such that the fixing portion 34 f comes into contact with the outer surface side of the flange portion 32 c of the conductive member 32. Further, ribs 34 e are formed on the periphery of the first insulating member 34 on the upper surface of the first insulating member 34. The rib 34e suppresses deformation of the first insulating member 34. Further, it is preferable that a rib 34 m is provided between the fixing portion 34 f and the peripheral rib 34 e of the first insulating member 34.
第1絶縁部材34の上面において幅方向の両端部には、それぞれ第2絶縁部材20bに固定される接続部34gが形成されている。この接続部34gは、第1絶縁部材34の本体部34kから封口体13側に伸びるように形成され、貫通孔34hを有する。この貫通孔34hに第2絶縁部材20bの接続部に設けられた突出部が嵌合することにより第1絶縁部材34と第2絶縁部材20bが固定される。 Connection portions 34g fixed to the second insulating member 20b are formed at both ends in the width direction on the upper surface of the first insulating member 34, respectively. The connecting portion 34g is formed so as to extend from the main body portion 34k of the first insulating member 34 toward the sealing body 13 and has a through hole 34h. The first insulating member 34 and the second insulating member 20b are fixed by fitting the protrusion provided at the connecting portion of the second insulating member 20b into the through hole 34h.
図5B及び図5Cに示すように、第1絶縁部材34の下面には、集電体16に形成された第1開孔16g、第2開孔16h、及び第3開孔16jにそれぞれ挿入される第1突起部34b〜第3突起部34dが形成されている。第1突起部34b及び第1突起部34cの先端面には凹部が設けられている。なお、図5B及び図5Cは、第1突起部34b〜第3突起部34dの先端部を拡径する前の状態を示している。また、第1絶縁部材34の下面において、第1絶縁部材34の長手方向の両端側には薄肉部34iが形成されている。 As shown in FIGS. 5B and 5C, the first insulating member 34 is inserted into the first opening 16g, the second opening 16h, and the third opening 16j formed in the current collector 16, respectively. First to third protrusions 34b to 34d are formed. Concave portions are provided on the tip surfaces of the first protrusion 34b and the first protrusion 34c. 5B and 5C show a state before the diameters of the distal ends of the first protrusion 34b to the third protrusion 34d are expanded. In addition, on the lower surface of the first insulating member 34, thin portions 34 i are formed on both ends in the longitudinal direction of the first insulating member 34.
固定部34fは、図6に示すように第1絶縁部材34の本体部34kから封口体13側に伸びる第1領域34f1と、この第1領域34f1に形成され、導電部材32側に突出する第2領域34f2とを有している。ここで、第1領域34f1は、第2絶縁部材34の本体部34kに対して垂直方向に伸びるように設けられていることが好ましい。図7〜10に示すように、この固定部34fが導電性部材32のフランジ部32cの外面側に当接し、引っ掛け固定されるようにして、第1絶縁部材34が導電性部材32に装着される。これにより、第1絶縁部材34と導電性部材32が一体的に固定される。このような構成を備えていると、角形二次電池10に振動・落下等により衝撃が加わっても電流遮断機構35が破損し難くなる。更に、第1絶縁部材34と集電体16が固定されていると、角形二次電池10に衝撃が加わり巻回電極体11が移動するように力が加わっても、集電体16と反転板33の接続部等にストレスが掛かり難くなるため、より信頼性の高い角形二次電池が得られる。 As shown in FIG. 6, the fixing portion 34 f is formed in a first region 34 f 1 extending from the main body portion 34 k of the first insulating member 34 toward the sealing body 13, and in the first region 34 f 1, and the first portion 34 f protruding toward the conductive member 32 side. 2 regions 34f2. Here, the first region 34f1 is preferably provided so as to extend in a direction perpendicular to the main body 34k of the second insulating member 34. As shown in FIGS. 7 to 10, the first insulating member 34 is attached to the conductive member 32 so that the fixing portion 34 f abuts on the outer surface side of the flange portion 32 c of the conductive member 32 and is hooked and fixed. The Thereby, the 1st insulating member 34 and the electroconductive member 32 are fixed integrally. With such a configuration, even if an impact is applied to the square secondary battery 10 due to vibration, dropping, or the like, the current interrupt mechanism 35 is not easily damaged. Further, when the first insulating member 34 and the current collector 16 are fixed, even if a force is applied to the rectangular secondary battery 10 so that the wound electrode body 11 is moved due to an impact on the prismatic secondary battery 10, the current collector 16 and the current collector 16 are reversed. Since it is difficult for stress to be applied to the connecting portion of the plate 33, a more reliable prismatic secondary battery can be obtained.
また、本実施形態の角形二次電池10では、第2領域34f2の先端部(導電性部材32側)の幅W1が、第2領域34f2の根本部(第1領域34f1との境界部分)の幅W2よりも小さくなっている。このため、第1絶縁部材34を導電部材32に装着する際、固定部34fが損傷することを確実に防止できる。また、第1絶縁部材34を導電部材32に装着する際に固定部34fに余計な負荷が掛からないため、固定部34fの耐久性の低下を防止できるため、電池使用時においても電流遮断機構の損傷を防止できる。 Further, in the prismatic secondary battery 10 of the present embodiment, the width W1 of the distal end portion (on the conductive member 32 side) of the second region 34f2 is the root portion of the second region 34f2 (the boundary portion with the first region 34f1). It is smaller than the width W2. For this reason, when attaching the 1st insulating member 34 to the electrically-conductive member 32, it can prevent reliably that the fixing | fixed part 34f is damaged. In addition, since no excessive load is applied to the fixing portion 34f when the first insulating member 34 is attached to the conductive member 32, the durability of the fixing portion 34f can be prevented from being lowered. Damage can be prevented.
更に、第2領域34f2の先端部(導電性部材32側)の厚みT1が、第2領域34f2の根本部(第1領域34f1との境界部分)の厚みT2よりも小さくなっている。ここで、第2領域34f2の上面は、第1絶縁部材34の本体部34kに対して傾斜している。これにより、第1絶縁部材34を導電部材32に装着する際に固定部34fに掛かる負荷をより低減できる。また、第2領域34f2の下面も、第1絶縁部材34の本体部34kに対して傾斜している。ここで、第2領域34f2の上面の第1絶縁部材34の本体部34kに対する傾斜角θ1は、第2領域34f2の下面の第1絶縁部材34の本体部34kに対する傾斜角θ2よりも大きくすることが好ましい。 Further, the thickness T1 of the distal end portion (on the conductive member 32 side) of the second region 34f2 is smaller than the thickness T2 of the root portion (boundary portion with the first region 34f1) of the second region 34f2. Here, the upper surface of the second region 34 f 2 is inclined with respect to the main body 34 k of the first insulating member 34. Thereby, when mounting the 1st insulating member 34 to the electrically-conductive member 32, the load concerning the fixing | fixed part 34f can be reduced more. The lower surface of the second region 34f2 is also inclined with respect to the main body 34k of the first insulating member 34. Here, the inclination angle θ1 of the upper surface of the second region 34f2 with respect to the main body portion 34k of the first insulating member 34 is larger than the inclination angle θ2 of the lower surface of the second region 34f2 with respect to the main body portion 34k of the first insulating member 34. Is preferred.
なお、実施形態の角形二次電池10では、第1絶縁部材34に形成されている固定部34fを導電部材32の筒状部32aに形成されたフランジ部32cの外周に引っ掛け固定するようにした例を示した。しかしながら、導電部材32の筒状部32aがフランジ部32cを備えていることは必ずしも必要な構成ではなく、筒状部32aの外周面に凹部を形成し、この凹部に第1絶縁部材34に形成されている固定部34fを引っ掛け固定することもできる。また、導電部材32の筒状部32aの上端部に第1絶縁部材34に形成されている固定部を固定することも考えられる。 In the prismatic secondary battery 10 of the embodiment, the fixing portion 34f formed on the first insulating member 34 is hooked and fixed to the outer periphery of the flange portion 32c formed on the cylindrical portion 32a of the conductive member 32. An example is shown. However, it is not always necessary that the cylindrical portion 32a of the conductive member 32 includes the flange portion 32c. A concave portion is formed in the outer peripheral surface of the cylindrical portion 32a, and the first insulating member 34 is formed in the concave portion. It is also possible to hook and fix the fixed portion 34f. It is also conceivable to fix the fixing portion formed on the first insulating member 34 to the upper end portion of the cylindrical portion 32a of the conductive member 32.
固定部34fの形状の変形例を図10に示す。図10は、固定部34fを上方(封口体側)から見た図である。図10Aに示すように、第2領域34f2の幅方向の両端を切り欠いたような形状とすることが出来る。図10Bに示すように、第2領域34f2の先端が尖がった形状とすることが出来る。図10C及び図10Dに示すように、第2領域34f2の側面部が湾曲する形状とすることが出来る。図10Eに示すように、第2領域34f2の幅方向の中央部分を円弧状に切り欠いたような形状とすることが出来る。図10Fに示すように、第2領域34f2を円弧状とすることが出来る。図10G及び図10Hに示すように、第1領域34f1の幅に比べて、第2領域34f2の根本部の幅を小さくすることが出来る。図10I及び図10Jに示すように、第1領域34f1に複数の第2領域34f2を設けることも出来る。 A modification of the shape of the fixing portion 34f is shown in FIG. FIG. 10 is a view of the fixing portion 34f as viewed from above (sealing body side). As shown in FIG. 10A, the second region 34f2 can have a shape that is notched at both ends in the width direction. As shown in FIG. 10B, the tip of the second region 34f2 can have a pointed shape. As shown in FIGS. 10C and 10D, the side surface of the second region 34f2 can be curved. As shown in FIG. 10E, the central portion in the width direction of the second region 34f2 can be shaped like a circular arc. As shown in FIG. 10F, the second region 34f2 can be arcuate. As shown in FIGS. 10G and 10H, the width of the root portion of the second region 34f2 can be made smaller than the width of the first region 34f1. As shown in FIGS. 10I and 10J, a plurality of second regions 34f2 may be provided in the first region 34f1.
上記実施形態の角形二次電池10では、導電部材32の筒状部32aと反転板33とを溶接接続する例を示したが、導電部材32の筒状部32aの下端を反転板33の周縁部にカシメ固定することにより、導電部材32の筒状部32aと反転板33を接続することも可能である。 In the prismatic secondary battery 10 of the above embodiment, the example in which the cylindrical portion 32a of the conductive member 32 and the reversing plate 33 are connected by welding has been shown, but the lower end of the cylindrical portion 32a of the conductive member 32 is the peripheral edge of the reversing plate 33. It is also possible to connect the cylindrical portion 32a of the conductive member 32 and the reversing plate 33 by caulking and fixing to the portion.
上記実施形態の角形二次電池10では、正極集電体16の第2領域16bが第1領域16aに2箇所形成されている例を示した。しかしながら、正極集電体の第2領域を1箇所のみ形成した角形二次電池に対しても適用可能である。 In the prismatic secondary battery 10 of the above-described embodiment, an example in which the second region 16b of the positive electrode current collector 16 is formed in two places in the first region 16a is shown. However, the present invention is also applicable to a prismatic secondary battery in which only one second region of the positive electrode current collector is formed.
上記実施形態の角形二次電池10では、集電体と芯体露出部の接続方法として抵抗溶接を用いた例を示したが、抵抗溶接に限定されず、レーザ溶接あるいは超音波溶接でもよい。 In the prismatic secondary battery 10 of the above-described embodiment, an example in which resistance welding is used as a connection method between the current collector and the core exposed portion is shown, but the present invention is not limited to resistance welding, and may be laser welding or ultrasonic welding.
角形二次電池としては、非水電解質二次電池に限定されず、アルカリ二次電池にも適用可能である。また、本発明の角形二次電池は車載用に限らず、太陽光発電、風力発電等の出力変動を抑制するための用途や夜間に電力をためて昼間に利用するための系統電力のピークシフト用途等の定置用蓄電池システムに用いることができる。 The prismatic secondary battery is not limited to a non-aqueous electrolyte secondary battery, and can be applied to an alkaline secondary battery. In addition, the prismatic secondary battery of the present invention is not limited to in-vehicle use, but is used for suppressing output fluctuations such as solar power generation and wind power generation, and peak shift of system power for use in the daytime for storing power at night It can be used for a stationary storage battery system such as an application.
10…角形二次電池 11…巻回電極体 12…電池外装体 13…封口体
14…正極芯体露出部 15…負極芯体露出部 16…正極集電体 16a…第1領域
16b…第2領域 16c…接続部形成用孔 16d…リブ 16e…薄肉領域 16
f…境界部 16g…第1開孔 16h…第2開孔 16j…第3開孔
17…正極端子部材 17a…筒状部 17b…貫通孔 17c…先端部 18…負極集電体 19…負極端子部材 20、21…絶縁部材 20a…第3絶縁部材 20b…第2絶縁部材 22a…電解液注液孔 22b…ガス排出弁 23…樹脂シート 24…正極用中間導電部材 24p…絶縁性中間部材 25…負極用中間導電部材 25p…絶縁性中間部材 30a…第1固定部 30b…第2固定部 30c…第3固定部 32…導電部材 32a…筒状部 32b…開孔 32c…フランジ部 33…反転板 34…第1絶縁部材 34a…第1の貫通孔 34b…第1突起部 34c…第2突起部 34d…第3突起部 34e…リブ 34f…固定部 34g…接続部 34h…貫通孔 34i…薄肉部 34k…本体部
35…電流遮断機構 36…端子栓 36a…頭部 36b…突出部
36c…係止部 36d…連結部 37…金属板
DESCRIPTION OF SYMBOLS 10 ... Square secondary battery 11 ... Winding electrode body 12 ... Battery exterior body 13 ... Sealing body 14 ... Positive electrode core exposed part 15 ... Negative electrode core exposed part 16 ... Positive electrode collector 16a ... 1st area | region 16b ... 2nd Area 16c: Connection forming hole 16d ... Rib 16e ... Thin area 16
f ... Boundary portion 16g ... first opening 16h ... second opening 16j ... third opening
DESCRIPTION OF SYMBOLS 17 ... Positive electrode terminal member 17a ... Cylindrical part 17b ... Through-hole 17c ... Tip part 18 ... Negative electrode collector 19 ... Negative electrode terminal member 20, 21 ... Insulating member 20a ... Third insulating member 20b ... Second insulating member 22a ... Electrolysis Liquid injection hole 22b ... gas discharge valve 23 ... resin sheet 24 ... positive electrode intermediate conductive member 24p ... insulating intermediate member 25 ... negative electrode intermediate conductive member 25p ... insulating intermediate member 30a ... first fixing portion 30b ... second fixing Part 30c ... Third fixing part 32 ... Conductive member 32a ... Tubular part 32b ... Open hole 32c ... Flange part 33 ... Reversing plate 34 ... First insulating member 34a ... First through hole 34b ... First protrusion 34c ... First 2 projection part 34d ... 3rd projection part 34e ... rib 34f ... fixed part 34g ... connection part 34h ... through-hole 34i ... thin part 34k ... main-body part 35 ... current interruption mechanism 36 ... terminal plug 36a ... head 3 b ... the protrusion
36c ... Locking part 36d ... Connecting part 37 ... Metal plate
Claims (8)
貫通孔を有し、前記外装体の開口を封止する封口体と、
正極板及び負極板を有し、前記外装体内に収容された電極体と、
前記正極板又は前記負極板に電気的に接続された集電体と、
前記集電体に電気的に接続され、前記封口体の貫通孔を貫通する端子部材と、
筒状部を有し、前記集電体及び前記端子部材に電気的に接続された導電部材と、
前記導電部材に接続され、電池内部の圧力が予め定めた所定値よりも大きくなると変形する反転板と、
第1の貫通孔を有し、前記反転板と前記集電体との間に配置された第1絶縁部材と、
を有し、前記反転板の変形に伴い前記電極体と前記端子部材の間の電気的接続が切断される角形二次電池であって、
前記反転板と前記集電体とが前記第1の貫通孔に対応する位置で接続されており、
前記導電部材の筒状部の前記電極体側の端部は前記反転板によって封止されており、
前記第1絶縁部材は固定部を有し、前記固定部は、前記第1絶縁部材の本体部から前記封口体側に伸びる第1領域と、前記第1領域に形成され、前記第1領域から前記導電部材側に突出した第2領域を有し、
前記固定部により前記第1絶縁部材は前記導電部材に固定されており、
前記固定部を上方(前記封口体側)から見たとき、前記第2領域における先端部の幅は、前記第2領域の根本部の幅よりも小さい角形二次電池。 An exterior body having an opening;
A sealing body having a through hole and sealing the opening of the exterior body;
An electrode body having a positive electrode plate and a negative electrode plate and housed in the outer package;
A current collector electrically connected to the positive electrode plate or the negative electrode plate;
A terminal member electrically connected to the current collector and penetrating the through hole of the sealing body;
A conductive member having a cylindrical portion and electrically connected to the current collector and the terminal member;
An inversion plate connected to the conductive member and deformed when the pressure inside the battery is greater than a predetermined value;
A first insulating member having a first through hole and disposed between the reversing plate and the current collector;
A prismatic secondary battery in which electrical connection between the electrode body and the terminal member is cut with deformation of the reversal plate,
The reversing plate and the current collector are connected at a position corresponding to the first through hole;
The end on the electrode body side of the cylindrical portion of the conductive member is sealed by the reversal plate,
The first insulating member has a fixing portion, and the fixing portion is formed in the first region extending from the main body portion of the first insulating member toward the sealing body, and from the first region to the first region. A second region protruding toward the conductive member;
The first insulating member is fixed to the conductive member by the fixing portion,
When the fixing portion is viewed from above (on the sealing body side) , the width of the tip portion in the second region is a rectangular secondary battery that is smaller than the width of the root portion of the second region.
前記第1絶縁部材は突起部を有し、
前記第1絶縁部材の突起部が、前記集電体の開孔又は切り欠きに接続されることにより
前記第1絶縁部材が前記集電体に固定されている請求項3に記載の角形二次電池。 The current collector has an opening or a notch,
The first insulating member has a protrusion;
The prismatic secondary according to claim 3, wherein the first insulating member is fixed to the current collector by connecting a protrusion of the first insulating member to an opening or a notch of the current collector. battery.
前記第1絶縁部材の突起部の先端には、前記第1絶縁部材の突起部において前記集電体の開孔又は切り欠き部の内部に位置する部分よりも径が大きい拡径部が形成されている請求項4に記載の角形二次電池。 The protrusion of the first insulating member passes through the opening or notch of the current collector,
A diameter-enlarged portion having a diameter larger than that of a portion of the protrusion of the first insulating member positioned inside the opening or notch of the current collector is formed at the tip of the protrusion of the first insulating member. The prismatic secondary battery according to claim 4.
前記第1絶縁部材と前記第2絶縁部材は固定されている請求項1〜5のいずれかに記載の角形二次電池。 A second insulating member is disposed between the sealing body and the conductive member,
The prismatic secondary battery according to claim 1, wherein the first insulating member and the second insulating member are fixed.
The prismatic secondary battery according to any one of claims 1 to 7 , wherein when the fixed portion is viewed from a side, a thickness of a tip portion in the second region is smaller than a thickness of a root portion of the second region.
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WO2018139451A1 (en) * | 2017-01-25 | 2018-08-02 | 三洋電機株式会社 | Secondary cell and production method therefor |
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