KR20120132353A - Electric storage device and insulation bag - Google Patents

Abstract

PURPOSE: An electrical storage device is provided to arrange a support element between a current collector, thereby capable of restraining displacement of a current collector toward an electrode, thereby being capable of restraining deformation or damages of a storage device. CONSTITUTION: An electrical storage device comprises: an electrode body which has a positive electrode foil, negative electrode foil, and a separator; positive and negative current collectors arranged in both end parts of the electrode body; a case accepting the electrode body and the current collector; a support element(13) extended from the positive current collector to the negative current collector. An insulating bag(27) in the storage device is arranged between the electrode and current collector, and the case, accepts the electrode and the current collector, and formed with the support element in one body.

Description

Capacitor and Insulation Bag {ELECTRIC STORAGE DEVICE AND INSULATION BAG}

One embodiment of the present invention relates to a power storage element and an insulating bag.

The electrical storage element can be used, for example, as "a nonaqueous electrolyte secondary battery such as a lithium ion secondary battery". The electrical storage element has an electrode body and the electrical power collector provided in the both sides, for example. As a power storage element of this kind, a nonaqueous electrolyte secondary battery disclosed in Japanese Patent Laid-Open No. 10-106536 is known. The electrode body disclosed in FIG. 4 of this publication has "the strip | belt-shaped positive electrode 5 and strip | belt-shaped negative electrode 6 wound by the spiral shape." Between these positive electrode 5 and negative electrode 6, "a pair of separator 7 for ensuring insulation is arrange | positioned." As shown in FIG. 8 of this publication, this electrode body is crushed so that "a shape seen from the axial direction (up-down direction) of a whirlpool becomes a rectangular parallelepiped with a rounded corner". As shown in FIG. 9 of this publication, the uncoated portion 4 of each pole is divided into five stacked bundles (short edges of electrodes). The current collector 10 of this battery is a metal member having "a plurality of grooves for receiving these laminated bundles". Each laminated bundle and the current collector 10 are welded by laser welding.

As disclosed in Japanese Unexamined Patent Application Publication No. 2010-272324, a nonaqueous electrolyte secondary having an "electrode body having a vortex center in left and right directions (lateral direction)" and "a current collector of a government disposed at the left and right ends thereof" Batteries have also been developed. The current collector of this battery has "a bifurcation in which the tip is branched". However, in this publication, only the arrangement is shown in the imaginary line with respect to the electrode body. The structure (that is, the junction structure of an ultrathin and an electrical power collector) for conducting-conductive joining of "the ultrathin of many governments protruding in the horizontal direction" and an electrical power collector is not disclosed at all.

An electrical storage element accommodates the electrode body which has a positive electrode foil, a negative electrode foil, and a separator for insulating these, the positive and negative electrical power collectors arrange | positioned at the both ends of the said electrode body, and the said electrode body and the said electrical power collector, It has a case which fixes "one end part of the said positive and negative electrical power collectors", and the support member extended from a positive electrical power collector to a negative electrical power collector.

According to this electrical storage element, the support member is arrange | positioned between electrical power collectors, and it can suppress that an electrical power collector displaces to the electrode body side. Therefore, even when vibration is applied to the power storage element, the above-described displacement of the current collector can be suppressed, and thus deformation or breakage of the power storage element can be suppressed.

BRIEF DESCRIPTION OF THE DRAWINGS The perspective view which shows "one support member and insulation bag which concerns on Example 1."
2 is a front view of some notch showing a nonaqueous electrolyte secondary battery.
3 is a side view of some notch showing the structure of a nonaqueous electrolyte secondary battery.
4 is an enlarged front view of some cutaways showing the structure around the current collector and the support member;
FIG. 5 is a perspective view illustrating a main part of the nonaqueous electrolyte secondary battery shown in FIG. 2. FIG.
6 is a perspective view showing the structure of an electrode body;
FIG. 7 is a cross-sectional view of an essential part showing a mounting state of the support member shown in FIG. 1. FIG.
FIG. 8 is a longitudinal sectional view of an essential part showing a mounting state of the support member shown in FIG. 1; FIG.
Fig. 9 is a development view of the "integral insulating bag integrally formed with a pair of supporting members according to the second embodiment".
FIG. 10 is a perspective view showing an assembly method of the unitary insulation bag shown in FIG. 9. FIG.
Fig. 11 is a partially cutaway front view of a battery bottom end showing the mounting structure of the integral insulating bag;
12 is a cross-sectional view of an essential part of a battery showing a mounting structure of an integral insulating bag.
The longitudinal cross-sectional view of the principal part of a battery which shows the mounting structure of an integral insulation bag.

BACKGROUND ART A battery such as the one described in the above-mentioned publication has been increasingly installed in traveling vehicles such as automobiles in recent years. In this case, as in JP-A-10-106536, when the electrode body and the current collector are simply joined by laser welding, the current collector and the ultrathin easily vibrate. Therefore, it is predicted that "the damage, such as a crack which generate | occur | produces in a joined part", tends to occur early by such a vibration continuing. Therefore, the development of "the electrical storage element provided with favorable earthquake resistance" is urgently needed.

Below, the electrical storage element (this electrical storage element) which concerns on this embodiment is demonstrated, referring drawings. In this embodiment, an example of a nonaqueous electrolyte secondary battery (lithium ion secondary battery) which is an example of the present power storage element will be described. 1 to 8 show Example 1, and FIGS. 9 to 13 show Example 2. FIG.

Example 1

The nonaqueous electrolyte secondary battery (lithium ion secondary battery) A according to Example 1 has an electrode body 1, a pair of current collectors 2 and 3, and an electrolyte solution (shown in FIGS. 2 to 5). Omitted) and a battery case 4 accommodating them. The battery case 4 is a hard board made of aluminum alloy, stainless steel alloy, or the like. The battery case 4 has a substantially rectangular parallelepiped shape (square shape; box shape) that is thin in one direction.

As shown in Figs. 2 and 3 and the like, the battery case 4 has a box-shaped main body case portion 4B without a lid and a top plate 4A. The case portion 4B and the top plate 4A can be integrated by laser welding or the like. The top plate 4A of the battery case 4 is provided with a "positive electrode part 5 electrically connected to the current collector 2" and "a negative electrode part 6 electrically connected to the current collector 3". . That is, the top plate 4A functions as "extreme terminal support wall 4a which supports the electrode parts 5 and 6 of the top part." The main body case part 4B has left and right current collector opposing walls 4b, front and rear main case walls 4c, and bottom walls 4d. That is, the main body case part 4B has a rectangular container shape provided with these 5 walls.

As shown in FIG. 1, FIG. 2, FIG. 3, etc., the secondary battery A further includes the insulating bag 27 made of an insulating material. The insulating bag 27 is disposed between them and the battery case 4 in a state in which the electrode body 1 and the pair of current collectors 2 and 3 are accommodated.

As shown in FIG. 1, the insulating bag 27 has a box shape without a lid so as to be accommodated in the body case part 4B without a gap (or almost without a gap). As shown in FIG. 1, FIG. 4, FIG. 7, FIG. 8, etc., the insulating bag 27 is equipped with the front-back side wall 27a, the left-right side wall 27b, and the bottom wall 27c. The insulating bag 27 is formed of synthetic resin of thin film form, for example. This insulating bag 27 is a box-less box type as shown in Fig. 1 by bending each of the walls 27a to c from the expanded state (the insulating bag in the same state is shown in Fig. 9). It can have a structure (assembled structure) which can be assembled into a shape (cuboid shape). At the left and right ends of the insulating bag 27, as shown in Fig. 4, the small side walls 27b are stacked in two layers. At the lower end portions of the left and right ends, two small side walls 27b correspond to the "protrusion pieces (protruding pieces 29a shown in Fig. 9) of the small area projected from the left and right ends of the bottom wall 27c. And omission). That is, this lower end part has the structure which overlapped three sheets. In addition, the insulating bag 27 may be formed by mold molding, and may have other structures.

As shown in FIG. 2, FIG. 5, and FIG. 6, the electrode body 1 has the positive electrode 7 and the negative electrode 8, and the "two separators 9 which are insulating materials provided between them." Has. That is, the electrode body 1 is a four-layer laminated structure. In the electrode body 1, these ultrathins 7 and 8 and the two separators 9 are wound in a spiral shape. And the electrode body 1 is formed in the roll body "the shape seen from the axial direction (P direction) of this vortex becomes a rectangle with rounded corners." For this reason, the electrode body 1 is a substantially rectangular parallelepiped which has "a circular arc-shaped part (curved surface) extended along a P direction". That is, as shown in FIG. 3 and the like, the electrode body 1 is thin along the "front and rear direction (arrow I direction) substantially orthogonal to the P direction" and vertically (orthogonally orthogonal to the P direction and the front and rear direction) Arrow II direction) ”. That is, the electrode body 1 has a rectangular parallelepiped shape with flat rounded corners.

The positive electrode foil 7 is "the strip-shaped aluminum foil to which the positive electrode active material was apply | coated". Negative electrode foil 8 is "a strip | belt-shaped copper foil to which the negative electrode active material was apply | coated." These positive electrode foils 7 and the negative electrode foils 8 are shifted from each other along the P direction. The end portion 7A of the positive electrode foil 7 and the end portion 8A of the negative electrode foil 8 are located opposite to each other along the P direction. The end portions 7A and 8A are "exposed portions of aluminum foil or copper foil, to which no active substance is applied." The end portions 7A and 8A have straight portions 7a and 8a (shown in the longitudinal direction in FIGS. 3 to 5). A plurality of straight portions 7a and 8a are laminated along the radial direction of the vortex. In the state where many linear parts 7a and 8a were bundled and laminated | stacked, it is electrically conductively bonded to the counter electrode plate-shaped part 2A of the electrical power collector 2, or the counter electrode plate-shaped part 3A of the electrical power collector 3, respectively. It is. 6, the space | interval of the ultra-thin 7 and 8 and the separator 9 is expanded.

As said positive electrode active material, "a well-known material which occludes and discharges lithium ion" can be used. As the positive electrode active material, for example, "a lithium-containing transition metal oxide having an α-NaFeO ₂ structure” can be used. The metal oxide is, for example, LiCoO _2, or "LiCoO ₂ a part of Co is substituted by" Ni, Mn and other transition metal or boron "". As the positive electrode active material, "a compound having a spinel crystal structure represented by LiMn ₂ O ₄ ", a polyanionic compound, or the like can be used. The polyanionic compound is, for example, LiFePO ₄ , LiFeSO ₄ , or “LiFePO ₄ or LiFeSO _{4 in which} some Fe is substituted with Co or Mn”.

In addition, the current collector 2, the current collector 3, the positive electrode foil 7, and the negative electrode foil 8 have the same structure. Therefore, only one side (negative electrode side) is basically described about these in order to avoid duplication of description. On the other side (positive electrode side), corresponding numerals are attached to the drawings.

The current collectors 2 and 3 will be described. The positive electrode current collector 2 made of aluminum or an aluminum alloy and the negative electrode current collector 3 made of copper or a copper alloy have the same structure. This structure will be described using the current collector 3 as an example. 2 to 5, the current collector 3 has a horizontal upper portion 11 and a vertical current collector portion 12. As shown in FIG. The horizontal upper portion 11 is locked (fixed) to the top plate 4A of the battery case 4. The vertical current collector 12 is a portion that is bent from the end of the top plate 4A of the current collector 3 and vertically lowered. Accordingly, the current collector 3 is a component having an approximately L shape when viewed from the front.

The horizontal upper portion 11 of the current collector 3 is in contact with the bottom surface 4u of the top plate 4A via the first insulating member 14 made of synthetic resin. The cross section of the 1st insulating member 14 is "angular U-shape with opening part facing down". Moreover, the horizontal upper part 11 is electrically connected to the electrode terminal 6 via the hole 11a formed in the inner edge part.

The vertical current collector 12 is electrically connected to the negative electrode foil 8 of the electrode body 1 via a pair of counter electrode plate-shaped portions 3A formed in parallel in the middle portion of the vertical direction thereof. . A pair of opposing plate shapes on both sides of the current collector base end side (upper side) and the current collector front end side (bottom side) of the counter electrode plate portion 3A (at least one of the current collector base end side and the current collector front end side). The part 3B is formed. The counter plate-shaped part 3B has a surface substantially orthogonal to the counter electrode plate-shaped part 3A.

3 A of pairs of opposing electrode plate-shaped parts are "plate-shaped members which protrude from the vertical collector part 12 substantially perpendicularly and inward (swirl axis P direction)." These pole plate-shaped portions 3A are arranged at a predetermined interval in the thickness direction (arrow I direction) of the electrode body 1. On both sides (upper and lower side) of the counter electrode plate-shaped portion 3A, a "reinforcement plate portion 3a which is folded and bent at an appropriate angle" is formed. Moreover, "triangular plate-shaped part 23 which has the reinforcing plate part 3a integrally" is provided in the both sides of 3 A of opposing electrode plate-shaped parts. The triangular plate-like portion 23 of the opposing electrode plate-shaped portion 3A has a shape such as "arranged in the front-rear direction (arrow I direction) via these hole portions 24").

The positive electrode terminal 5 is made of aluminum, for example. In addition, the negative electrode terminal 6 is made of copper, for example. These terminals have the same general structure as each other. Therefore, here, one electrode terminal 6 will be described. As shown in Figs. 2 to 5 (particularly Fig. 4), the electrode terminal 6 has a rivet bolt structure. That is, the electrode terminal 6 has the upper male screw part 6c, the "square body part 6b which is in the middle of an up-down direction", and the cylindrical lower part 6a. The male screw portion 6c is erected on the upper side of the rectangular body portion 6b in order to be electrically connected to a lead wire (not shown). The quadrangular body part 6b is fitted to the second insulating member 15 made of synthetic resin on the upper side of the "top plate 4A which is the pole terminal support wall 4a."

The communication part 15a of the 2nd insulating member 15 is inserted in the round hole (omission of swelling) of the top plate 4A, and the round hole (omission of swelling) of the 1st insulating member 14. As shown in FIG. The cylindrical lower portion 6a of the electrode terminal 6 is inserted into the communication portion 15a and the round hole 11a of the horizontal upper portion 11 from above. The lower end of the cylindrical lower part 6a is crushed (coked) with respect to the lower surface of the horizontal upper part 11. As a result, the cylindrical lower portion 6a is electrically connected to the horizontal upper portion 11 of the current collector 3. Thus, the cylindrical lower part 6a and the horizontal upper part 11 are electrically connected through the 1st insulating member 14 and the 2nd insulating member 15. As shown in FIG. As a result, the electrode terminal 6 is attached to the top plate 4A in a state insulated from the top plate 4A.

Mainly, the junction part 10 (current collector structure) of one current collector 3 will be briefly described. As shown in FIGS. 2 to 4 and 7, the bonding portion 10 is a part of the counter electrode plate-shaped portion 3A of the current collector 3, and “the number of end portions 8A of the ultra-thin 8 is large. (A plurality of examples) ”and a part which is ultrasonically welded”. In the vicinity of the junction part 10 of 3 A of counter electrode plate-shaped parts, the plate-shaped metal clip 20 is arrange | positioned. A plurality of stacked end portions 8A (that is, an ultrathin 8A group) are sandwiched between the clip 20 and the "junction 10 of the counter electrode plate portion 3A", and are ultrasonically welded to the junction 10. It is. Moreover, the clip 19 similar to the clip 20 is provided also in the junction part 10 of the electrical power collector 2 of a positive electrode side. For example, the clip 19 may be made of aluminum, and the clip 20 may be made of copper.

Next, the supporting member 13 is demonstrated. As shown in FIG. 5, the secondary battery A of Example 1 has a supporting member 13. This support member 13 suppresses "the pair of collectors 2 and 3 rocking in the left-right direction (P direction)". For this reason, the support member 13 is arrange | positioned outside the electrode body 1. As shown in FIGS. 1 to 5, 7 and 8, the supporting member 13 extends from one current collector 2 to the other current collector 3 (current collector 2). And between the collector 3). The supporting member 13 is provided in the "gap S between the electrode body 1 and the battery case 4".

Specifically, as shown in FIGS. 1 and 2 to 5, the support member 13 has a pair of vertical support portions 25 and a pair of horizontal support portions 26. The vertical support part 25 has an elongate shape extended in the up-down direction substantially orthogonal to the P direction. The horizontal support part 26 is in contact with "both ends of the longitudinal direction of the pair of vertical support parts 25" (connecting both ends). Therefore, the support member 13 is a frame body "the shape seen from the front-back direction becomes a rectangular frame shape."

The vertical support part 25 is arrange | positioned at the vertical space part Ts (an example of the space | gap S) so that the counter electrode plate shape parts 2A and 3A may be followed (refer FIG. 7). The vertical gap Ts is a gap between the ends 7A and 8A of the ultrathins 7 and 8 and the battery case 4.

The horizontal support part 26 is arrange | positioned at the horizontal space | gap part Ys (an example of the space | gap S) (refer FIG. 8). The horizontal gap Ys is a gap between the "cylindrical surface 1E above and below the electrode body 1" and the battery case 4 (in detail, the main case wall 4c).

As shown to FIG. 1 and FIG. 7, the "cross section perpendicular | vertical to an up-down direction" of the vertical support part 25 is pentagonal. That is, this cross section is formed by "the corner part approaching the edge part 8A of the ultra-thin 8 in the case where this cross section is a thin and elongate rectangle in a P direction obliquely". And the vertical support part 25 which has such a cross section is extended in the up-down direction (direction substantially orthogonal to a P direction). Thus, the vertical support part 25 is comprised so that it may be arrange | positioned in the "vertical space part Ts which is wide in the left-right direction, and has a narrow cross-sectional shape in the front-back direction." Thereby, it becomes possible to use this space | gap part Ts effectively.

On the other hand, as shown to FIG. 1 and FIG. 8, the "cross section perpendicular | vertical to the P direction" of the horizontal support part 26 is also pentagonal. That is, this cross section is formed by "the corner part proximate to the electrode body 1 in the case where this cross section is a thin elongate rectangle in an up-down direction" at an oblique angle. " And the horizontal support part 26 which has such a cross section extends in the left-right direction (P direction). Thus, the horizontal support part 26 is comprised so that it may arrange | position in the space | gap S "cross section perpendicular | vertical to a P direction becomes substantially triangular" without difficulty. Thereby, it becomes possible to use this space | gap S effectively.

The pair of longitudinal supports 25 has a cross section 25a. These end surfaces 25a face the "inner side surface 2b of the opposing plate-shaped portion 2B of the current collector 2 and the inner side surface 3b of the opposing plate-shaped portion 3B of the current collector 3". Abut (or face to face). As a result, the pair of vertical support portions 25 restricts the current collectors 2 and 3 from moving (or hardly moving) to the inside (the direction in which they exist). That is, the vertical support part 25 has "the function which supports the electrical power collectors 2 and 3 regarding P direction." As a result, the current collectors 2 and 3 are in a state in which movement (shake, displacement, or deformation) inward is suppressed.

As described above, the “electrode body 1 and the current collectors 2 and 3” are covered with an insulating bag 27. Therefore, to be precise, the transverse void portion Ys that accommodates the transverse support 26 is the gap portion between the cylindrical surface 1E of the electrode body 1 and the insulating bag 27. In addition, the vertical space | gap part Ts which accommodates the vertical support part 25 is a clearance gap part between the "ends 7A and 8A of the ultrathins 7 and 8" and the insulating bag 27. As shown in FIG. The material of the support member 13 may be synthetic resin such as PP (polypropylene) and PE (polyethylene). In addition, this material may be other than these as long as it is a material which has insulation, electrolyte resistance, and "strength which can support the collectors 2 and 3".

Next, the reason for providing the support member 13 and the action and effect by the support member 13 will be described in detail.

As shown in FIG. 4, in the nonaqueous electrolyte secondary battery A, the electrode terminals 5 and 6 are provided on the top plate 4A of the battery case 4. The top plate 4A of the battery case 4 fixes the horizontal upper portion 11 of the current collectors 2 and 3. That is, the top plate 4A supports "one end (horizontal upper portion 11) of the current collectors 2 and 3". The current collectors 2 and 3 are supported by the vertical current collector 12 so that the electrode body 1 can be suspended inside the battery case 4.

As the current collectors 2 and 3 are disclosed in Japanese Patent Laid-Open No. 2010-272324 described above, only the upper part may be supported. Alternatively, the current collector may be supported in both up and down directions by grounding the lower end of the current collector to the bottom of the battery case 4 as in the second embodiment (described later) shown in FIGS. 10 and 11. In either case, basically only the upper portions of the pair of current collectors 2 and 3 are supported. The vertical current collectors 12 of the current collectors 2 and 3 support the electrode body 1 so as to be suspended.

Therefore, when the secondary battery A receives the vibration of the horizontal direction (especially, the P direction which is a direction orthogonal to the surface of the electrical power collectors 2 and 3), the vertical electrical power collector 12 is inside the battery case 4 In addition, the electrode body 1 is easily vibrated in the P direction. Moreover, the current collector opposing wall 4b (or the small side wall 27b of the insulating bag 27) of the battery case 4 exists in the "outer side along the P direction of the vertical collector 12". For this reason, the vertical collector 12 does not move outward along the P direction. However, in the inward direction along the P direction, there is no member supporting the vertical current collector 12. For this reason, when the secondary battery A is subjected to the vibration as described above, the vertical current collector 12 (current collectors 2 and 3) are attracted to the electrode body 1 and are easily moved (displaced) inward. have.

When such displacement and restoration of the vertical current collector 12 are repeated, the end portion 7A of the ultrathin 7 and the end portion 8A of the ultrathin 8 in the electrode body 1 are buckled and tensioned. Receive the force repeatedly in the direction of the direction. For this reason, the edge parts 7A and 8A are deformed repeatedly. As a result, there is a possibility that cracks and / or breaks are caused in the ultrathins 7 and 8 (particularly, the ends 7A and 8A). This is not suitable when the battery is installed in a place where the vibration of the interior of the vehicle is high. The support member 13 solves or ameliorates this problem.

By the way, the shape seen from the P direction of the electrode body 1 is a rectangle with rounded corners (refer FIG. 3). Therefore, the electrode body 1 has the cylindrical surface 1E up and down. For this reason, when the electrode body 1 is accommodated in the rectangular battery case 4, between the "front and rear main case wall 4c and the top plate 4A", and the upper cylindrical surface 1E, and the "front and rear main case." In the four systems between the wall 4c and the bottom wall 4d '' and the lower cylindrical surface 1E, a horizontal gap Ys extending from side to side occurs. And to "the end 7A where the positive electrode foil 7 which is electrically connected to the counter electrode plate-shaped part 2A of the collector 2 is tied," and the counter electrode plate-shaped part 3A of the collector 3 The vertical gap portion Ts is formed between the end portion 8A where the negative electrode foil 8 to be electrically connected is bundled '' and the main case wall 4c before and after. In the secondary battery A of the present embodiment, the supporting member 13 is disposed in these horizontal gaps Ys and vertical gaps Ts. That is, these space | gap parts are used effectively. For this reason, it is not necessary to provide "dedicated arrangement space for arrange | positioning the support member 13".

Thus, in the nonaqueous electrolyte secondary battery A, the vortex electrode body 1 is accommodated in the rectangular battery case 4. For this reason, the support member 13 has a square shape so that it may be accommodated in the empty space (space | interval S) containing the vertical space part Ts and the horizontal space part Ys without difficulty. Accordingly, the current collectors 2 and 3 move in the P direction (the plane direction of the vertical current collector 12) without performing “all modifications including structural changes, parts, and the like” for the secondary battery A. FIG. (Including vibration movement) ”can be suppressed or eliminated.

Thus, by providing the support member 13, the structure which supports the electrical power collectors 2 and 3 when the nonaqueous electrolyte secondary battery A receives the vibration of the horizontal direction (especially P direction) is built up. . For this reason, "the dragging of the electrode body 1 and moving the collectors 2 and 3 in the P direction" is prevented or suppressed. As a result, it is possible to suppress the vertical current collector portion 12 of the current collectors 2 and 3 from being shaken even in a vibration-mounted installation environment such as an automobile. As a result, "the" end 7A of the ultrathin 7 and the end A of the ultrathin 8 "in the electrode body 1 are repeatedly deformed, so that the ultrathins 7 and 8 (particularly, the end 7A and 8A)), problems such as cracks and / or fractures '' are almost eliminated. Thus, the nonaqueous electrolyte secondary battery A with improved durability is realized.

[Example 2]

The nonaqueous electrolyte secondary battery A of Example 2 has the insulating bag 27 formed integrally with the support member 13 in the structure of the nonaqueous electrolyte secondary battery of Example 1 (refer FIG. 9).

As described above, the battery case 4 is formed of a conductive material such as aluminum alloy. Therefore, in order to "insulate the battery case 4 and the" electrode body 1 and the collectors 2 and 3 which are internal parts ", the secondary battery A is equipped with the insulating bag 27. The insulating bag 27 is made of an insulating material. The insulating bag 27 is inserted into the battery case 4 in a state where the electrode body 1 and the current collectors 2 and 3 are accommodated.

In the secondary battery A of Example 2, this insulating bag 27 and the support member 13 are integrally formed (refer FIG. 9 and FIG. 13). As shown in FIG. 10 and FIG. 11, in the secondary battery A of Example 2, the short side walls 41 serving as the insulating caps are covered with the lower ends of the current collectors 2 and 3. The current collectors 2 and 3 extend downward so that these lower end portions reach the bottom wall of the battery case 4 (notation of swelling).

As shown in Figs. 9 and 10, the insulating bag (hereinafter referred to as an integral insulating bag) 27 having the support member 13 integrally is "an element is formed from a substantially flat plate state. By bending, it has a structure (assembly type | mold structure) which can be assembled into the shape (cubical shape) without a lid as shown in FIG. That is, as shown in FIG. 9, the integral insulating bag 27 is formed with the thin synthetic resin. The integrated insulating bag 27 is provided with a pair of opposing side walls 28 which have the support member 13, and the bottom wall 29 located between them. Each side wall 28 is provided with "a pair of (over four) overlapping walls 28a protruding outwardly". At both ends of the bottom wall 29, "a pair of protrusion pieces 29a which protruded outward" are provided.

The contralateral wall 28 has a pair of convex vertical frame portions 30, a pair of convex horizontal frame portions 31, and a planar wall 32. The convex horizontal frame part 31 connects both ends of the convex vertical frame part 30. The planar wall 32 is a recess in these four frame portions. In this way, the side wall 28 is a plate having irregularities. The pair of convex vertical frame portions 30 and the pair of convex horizontal frame portions 31 constitute a “frame having a square shape”. This frame body constitutes the support member 13. The pair of contralateral walls 28 and the bottom wall 29 are in series. Between the adjacent overlapping wall 28a and the protrusion piece 29a, the "cutting depth k which makes it possible to bend these independently" is formed. In addition, the thin wire x shown in FIG. 9 and FIG. 10 is a bending schedule line.

As shown in FIG. 12, the convex vertical frame portion 30 includes an outer wall 33, a front vertical wall 34, an inclined vertical wall 35, and a very short side vertical wall 36. Have The convex vertical frame part 30 is formed "to fit snugly in the vertical space part Ts." As shown in FIG. 13, the convex horizontal frame portion 31 includes a horizontal wall 37, a front horizontal wall 38, an inclined horizontal wall 39, and a short side horizontal wall 40 having a very short width. Have The convex horizontal frame part 31 is formed "to fit snugly in the horizontal space | gap part Ys." The thickness of each wall 33-40 may be thicker than thickness (basic thickness), such as the flat wall 32. As shown in FIG. In this case, the strength and rigidity of each of the walls 33 to 40 are improved. For this reason, the "function of supporting the collectors 2 and 3" of the convex vertical frame part 30 and the convex horizontal frame part 31 is improved.

Here, the procedure for "assembling the integral insulating bag 27 in a developed state (refer FIG. 9) so that it may become box shape without a lid" is shown. First, as shown in FIG. 10, the left and right contralateral walls 28 are bent as shown by an arrow on the basis of the bottom wall 29 to produce them. Then, each protrusion piece 29a is produced by bending like an arrow. From this, the "four overlapping walls 28a of the both side walls 28" are bent as shown by the arrow. Thereby, the integral insulating bag 27 is assembled in the box shape without a lid (refer FIG. 12 and FIG. 13). As shown in FIG. 11, a pair of overlapping wall 28a overlaps the outer side of the protrusion piece 29a. As a result, the short side wall 41 of the integrated insulating bag 27 is formed. These protruding pieces 29a and the pair of overlapping walls 28a may be bonded by an adhesive or the like, or may simply be in an overlapping state.

The protruding piece 29a and the pair of overlapping walls 28a constituting the short side wall 41 may be inseparable (or difficult) by being bonded by an adhesive or the like. In this case, as shown by an imaginary line (double dashed line) in FIG. 10, before assembling the integral insulating bag 27, the "electrode body 1 provided with the collectors 2 and 3, etc." is a low wall in advance. It may be stored in (29). And from this state, you may perform each bending process mentioned above. The reason is as follows. 12 and 13, when the integrated insulating bag 27 is in an assembled state covering the electrode body 1, the supporting member 13 (in detail, the upper convex horizontal frame portion ( 31) is introduced into the thickness width of the electrode body 1 (in the horizontal gap portion Ys). Therefore, after assembling the integral insulating bag 27 in a box shape without a lid, the "electrode body 1 comprising the current collectors 2 and 3 '' is referred to as a" pair of the integral insulating bag 27. It is impossible or difficult to insert into the inside of the upper opening through which the convex horizontal frame portion 31 protrudes.

However, the integrated insulating bag 27 may be formed of "an insulating material having flexibility, such as plastic (synthetic resin)." In such a case, it may become possible to put the above-mentioned force depending on the dimension of each part. Therefore, at the time of assembling the integrated insulating bag 27, "whether or not the electrode body 1 having the current collectors 2 and 3 is loaded on the bottom wall 29 in advance" is referred to as "integral insulation. It is judged appropriately according to the structure of the bag 27 (whether or not the end side wall 41 is adhesively formed, etc.) and the material of the integral insulating bag 27 ".

When the integral insulating bag 27 is assembled into a bag shape without a lid, and the "electrode body 1 having current collectors 2 and 3" is accommodated therein, as shown in FIGS. As described above, the convex vertical frame portion 30 fits into the vertical gap Ts, and the convex horizontal frame portion 31 fits into the horizontal gap Ys. And in this state, the outer side wall 33 of the convex vertical frame part 30 in the support member 13 is the inner side surface (the counter plate-shaped part 2B of the collector 2 corresponding). 2b) and the inner surface 3b of the opposing plate-shaped portion 3B of the current collector 3 " are in contact with each other (or are in contact with each other). In addition, a very small gap may be present between the outer surface wall 33 and the inner surfaces 2b and 3b. Also in this case, the "effect by the support member 13" mentioned above can be acquired.

The nonaqueous electrolyte secondary battery A of Example 2 has the same effect as the battery of Example 1. In addition, in Example 2, the support member 13 can also be attached by attaching the insulating bag 27 to the electrode body 1. Thereby, assembly efficiency (production efficiency) can be improved. That is, the integral insulating bag 27 provided with the supporting member 13 can reduce the number of parts compared with the supporting member 13 and the insulating bag 27 of Embodiment 1 shown in FIG. That is, instead of three parts (a pair of support member 13 + insulating bag 27), one part (integral insulating bag 27) is used. Therefore, it becomes possible to reduce cost and reduce the number of assembly steps.

Thus, in the manufacture of the nonaqueous electrolyte secondary battery A of Example 2, the integral insulating bag 27 integrally formed with the support member 13 is prepared in a developed state. Then, the integrated insulating bag 27 is assembled so that the support member 13 is positioned at the horizontal gap Ys and / or the vertical gap Ts between the pair of current collectors 2 and 3. Thereby, the integral insulation bag 27 becomes "a predetermined | prescribed bag shape which accommodates the electrode body 1 and a pair of collectors 2 and 3".

Therefore, in the manufacturing method of the battery A of Example 2, while the integral insulating bag 27 of the expanded state is bent and made into a bag shape, the electrode body provided with the collectors 2 and 3 inside the integral insulating bag 27 ( 1) ”. As a result, the following unique effects are obtained. That is, the integral insulating bag 27 is formed by "the protrusion pieces 29a and the pair of overlapping walls 28a constituting the short side walls 41 of the integrated insulating bag 27 are bonded by an adhesive agent". Even when it is in the state which cannot be developed again, the support member 13 can be arrange | positioned in a predetermined location, avoiding the problem of being unable to accommodate an electrode body in the integrated insulation bag 27, etc. . That is, even in such a case, it is possible to assemble the integral insulating bag 27 without problems.

[Other Embodiments]

As shown in FIG. 10 and FIG. 11, the lower end portions of the opposing plate-shaped portions 2B and 3B below the current collectors 2 and 3 may extend until they reach the bottom face of the battery case 4. In addition, although illustration is abbreviate | omitted, the electrical power collectors 2 and 3 do not need to have a substantially opposite plate-shaped part (substantially). When the electrode body 1 is formed so that "a shape seen from the P direction becomes an elliptical shape", although not shown, the horizontal support part 26 of the upper and lower sides of the support member 13 is "the upper and lower ends of the vertical support part 25." Rather, it may be disposed in a portion of the inner side along the vertical direction. Moreover, the support member 13 may be "a shape which acts on the lower opposing plate-shaped parts 2B and 3B, and does not act on the upper opposing plate-shaped parts 2B and 3B." The support member 13 may be a shape that acts on the upper opposing plate portions 2B and 3B and does not act on the lower opposing plate portions 2B and 3B.

In the secondary battery A shown in the present embodiment, the top plate 4A of the case 4 is disposed above the electrode body 1. However, the present invention is not limited to this. In this secondary battery A, even if the top plate 4A is arranged (for example, even if the top plate 4A is arranged to extend in the longitudinal direction), it is possible to suppress the shaking of the current collector. Do.

In addition, in this embodiment, the battery case 4 has a substantially rectangular parallelepiped shape (square shape; box shape) which is thin in one direction. However, the present invention is not limited thereto, and the shape of the battery case 4 may be any shape as long as it can accommodate the electrode body 1 and the current collectors 2 and 3.

In addition, in this embodiment, this power storage element is shown as a secondary battery A. FIG. However, the power storage device is not limited to a secondary battery, but can also be applied to other power storage devices (for example, electric double layer capacitors).

In addition, as the electrode body 1, the linear portions 7a and 8a along the vertical direction (arrow II direction) may be selected as the plurality of end portions 7A and 8A. In addition, as an example of the support member 13, as shown in FIGS. 1-5, FIG. 7, and FIG. 8, the state which spans these collectors 2 and 3 between a pair of collectors 2 and 3 is shown. May be provided through the space S between the electrode body 1 and the battery case 4.

In addition, the vertical support part 25 is ultra-thin 7 in the state along the opposing board-shaped parts 2B and 3B formed in both the collector base end side and the collector front-end side of the counter electrode plate-shaped parts 2A and 3A. And the vertical gap Ts (an example of the gap S) between the ends 7A and 8A of the 8) and the battery case 4 (see FIG. 7).

In addition, as shown in Fig. 7, the vertical support portion 25 is formed to have a pentagonal cross-sectional shape in which the corner portions, which are inward in the left and right and front and rear directions in the long rectangle along the vortex axis P, are obliquely cut, It may be arrange | positioned in the state extended in the up-down direction (an example of the direction which a vortex intersects the axial center P). In addition, as shown in FIG. 8, the horizontal support part 26 is formed in what has a 5-sided cross-sectional shape in which the corner part which becomes back, front and back in an oblong rectangle in an up-down direction, and inward in an up-down direction is cut obliquely, It may be arrange | positioned in the state extended in the direction (direction in which a whirlpool follows the axial center P).

Each vertical support portion 25 serves to support a portion that restricts the left and right current collectors 2 and 3 from moving (or hard to move) in the direction of existence of each other, that is, each of the opposing plate-shaped portions 2B and 3B. You may function as a location. The end face 25a in the left and right direction of each vertical support portion 25 faces the inner surfaces 2b and 3b of the opposing plate-shaped portions 2B and 3B on the upper and lower sides of the current collectors 2 and 3, respectively. The dimensions may be in contact with or in contact with each other.

In addition, the convex vertical frame part 30 and the convex horizontal frame part 31 can also be represented by the concave vertical frame part 30 and the concave horizontal frame part 31, respectively. The concave vertical frame portion 30 may be formed in a concave manner into the vertical gap Ts in the inward direction. The concave horizontal frame part 31 may be formed in the transverse space | gap part Ys in the state recessed inwardly.

In addition, one object of the present embodiment is to improve the use of a traveling vehicle with a structure having a “shockproof property in a state where a plurality of ultrathin and current collectors are electrically bonded together in a spiral electrode body”. It is to provide a power storage device.

The first power storage element according to the present embodiment,

"Swirl electrode body 1 formed by winding each positive and negative ultra-thin 7 and 8 and the insulating separator 9 provided between these 7 and 8," and "The said electrode body ( In the vortex axis P direction of 1), a pair of negative current collectors 2 and 3 which are allocated to both sides of the electrode body 1, and the electrode body 1 and the current collector 2 and 3) having a rectangular case 4 for accommodating 3),

"The ends 7A and 8A of the said ultra-thin 7 and 8 arrange | positioned in and around the radial direction of the said electrode body 1" and the said electrical power collectors 2 and 3 are electrically joined, and a pair of said A supporting member 13 in a state spanning between the current collectors 2 and 3 is provided through the space S between the electrode body 1 and the case 4.

In the first power storage device, the second power storage device according to the present embodiment includes:

The current collectors 2 and 3 have opposite electrode plate-shaped portions 2A and 3A having a "surface that extends in the direction along the vortex axis P" and "are wider in the direction intersecting with the vortex axis P. And a facing plate-shaped portion 2B and 3B formed on at least one of the current collector base end side and the current collector front end side of the counter electrode plate-shaped portions 2A and 3A. And the electrode body 1 is formed to exhibit a rectangle with rounded corners in the vortex axis P direction,

"The plurality of ultra-thin end portions 7A and 8A disposed in and out of the radial direction of the electrode body 1" and the counter electrode plate-shaped portions 2A and 3A are electrically connected to each other, and the supporting member 13 Is disposed over the opposing plate portions 2B and 3B.

In the third power storage element according to the present embodiment, in the second power storage element,

The pair of pairs of the support members 13 "connects a pair of longitudinal supports 25 having an elongated shape along the direction crossing the vortex axis P" and both ends of the longitudinal supports 25 in the longitudinal direction. Square shape having a horizontal support portion 26 ”.

As for the 4th power storage element which concerns on this embodiment, in a 3rd power storage element,

The vertical support portion 25 is the ultrathin end portions 7A and 8A and the case in the state along the opposing plate-shaped portions 2B and 3B formed on both of the current collector base end side and the current collector front end side. It is arranged in the vertical gap Ts between (4), and the said horizontal support part 26 is arrange | positioned in the horizontal gap Ys between the cylindrical surface 1E in the said electrode body 1, and the said case 4, have.

The fifth power storage device according to the present embodiment is the fourth power storage device,

The said support member 13 is provided in each of the both sides of the thickness direction of the said electrode body 1 in the state which can contact the edge part of the width direction in the said opposing plate-shaped parts 2B and 3B.

As for the 6th power storage element which concerns on this embodiment, in any 1st thru | or 5th power storage element,

The support member 13 is made of a synthetic resin material.

As for the 7th power storage element which concerns on this embodiment, in any 1st thru | or 6th power storage element,

Between the "electrode body 1 and the said pair of collectors 2 and 3" and "the said case 4 made of a conductive material", "these electrode bodies 1 and each collector 2 and 3" are connected. The insulating bag 27 made of an insulating material to be accommodated ”is provided, and the supporting member 13 is integrally formed with the insulating bag 27.

According to the first power storage element, a support member is disposed between a pair of current collectors. As a result, "the current collectors move in the mutually existing direction" is suppressed or prevented. Since movement and / or vibration of an electrical power collector are suppressed or prevented, "repetitive movement (vibration) of the ultra-thin end joined to an electrical power collector in a vortex axial direction" is reduced or eliminated. As a result, it becomes possible to prevent ultra-thin early cracking and / or breaking. Thus, the durability and / or reliability of the power storage element is improved.

Moreover, the supporting member which is a means for this is provided through the space | gap between a spiral electrode body and a case. For this reason, it is unnecessary to reduce the volume of the electrode body or to form a dedicated arrangement space between the electrode body and the case. That is, the structure excellent in rationality, such as "the support member can be arrange | positioned, maintaining the capacity | capacitance (battery capacity) of an electrical storage element" is implement | achieved. As a result, it is possible to provide a power storage device which has a structure having a shockproof structure and which can be suitably used in a traveling vehicle in a state in which the "a plurality of ultra-thin in the swirl-shaped electrode body" and the current collector are electrically connected. .

According to the 2nd power storage element, "the counter electrode plate shape part joined to the some ultra-thin in a collector" is set as the wall surface extended in the direction along a vortex axis center. For this reason, the counter electrode plate-shaped part is hard to respond to a supporting action. For this reason, by "applying the support member which has a support action to the opposing board-shaped parts located in the both sides", "useful electrical storage element which can exhibit the effective vibration prevention function based on the situation (for example, Nonaqueous electrolyte secondary battery) " That is, the support member is a structure which abuts against the counter plate-shaped part which faces this face. For this reason, even if there is some dimensional error and / or product error, the said effect by a 1st electrical storage element can be exhibited more reliably.

According to the 3rd power storage element, a support member is formed in "the square shape which consists of a pair of vertical support part and a pair of horizontal support part." For this reason, the clearance gap between an electrode body and a case can be utilized effectively. Moreover, the electrical storage element which has "the rational support member excellent in strength and rigidity" can be provided.

According to the fourth power storage element, the support member is composed of a vertical support portion disposed in the "vertical void portion between the end portion of the ultrathin and the case" and a horizontal support portion disposed in the "lateral void portion between the cylindrical surface of the electrode body and the case". do. Thereby, while using a space efficiently, using the "vertical space formed horizontally at the edge part of foil, the large square support member which can act reliably to a collector on a large surface", it is stable so that a position may not shift. Can be installed in a supported state.

In the fifth power storage element, support members each having a square shape are provided on both sides of the electrode body. For this reason, a well-balanced power storage element can be configured. Therefore, the said effect by a 4th electrical storage element can be acquired more reliably.

According to the sixth power storage element, the support member is made of synthetic resin. Thereby, a support member can be comprised lightly and inexpensively. Therefore, it becomes possible to provide a power storage element in a preferable state as a product.

In the seventh power storage element, "an insulating bag provided to insulate between the current collector and the electrode body" and the case is formed integrally with the support member. The support member is also equipped by equipping an insulating bag. For this reason, assembly property is improved. Moreover, any one of the above effects by the first to sixth power storage elements can be obtained. In addition, the cost can be reduced by reducing the number of parts.

Claims (12)

An electrode body 1 having a positive electrode foil 7, a negative electrode foil 8, and a separator 9 for insulating these,
Positive and negative current collectors 2 and 3 disposed at both ends of the electrode body 1,
A case 4 accommodating the electrode body 1 and the current collectors 2 and 3;
The electrical storage element A which has the support member 13 which extends from the positive electrical power collector 2 to the negative electrical power collector 3. The method of claim 1,
The electrical storage element (A) in which the said case (4) fixes the one end part (11) of the said positive and negative electrical power collectors (2 and 3). The method of claim 2,
The electrical storage element (A) in which the said support member (13) is arrange | positioned between the said electrode body (1) and the said case (4). The method of claim 3,
The positive and negative current collectors 2 and 3 have opposing plate-shaped portions 2B and 3B,
The electrical storage element (A) in which the said support member (13) abuts against the opposing plate-shaped parts (2B and 3B) of both collectors (2 and 3). 5. The method of claim 4,
The pair of support members 13 extends along the opposing plate-shaped portions 2B and 3B of each of the current collectors 2 and 3 and abuts against these opposing plate-shaped portions 2B and 3B. Vertical support section 25,
The electrical storage element (A) which has the horizontal support part 26 which abuts on both sides of the said pair of vertical support part 25. As shown in FIG. The method of claim 5,
The electrode body 1 has a roll body in which the positive electrode foil 7, the negative electrode foil 8, and the separator 9 are wound in a spiral shape,
The current collectors 2 and 3 are disposed at both ends in the axial direction of the roll body,
The electrical storage element (A) in which the said horizontal support part (26) is arrange | positioned in the horizontal gap part (Ys) between the curved surface (1E) of the said roll body, and the said case (4). The method according to claim 6,
Two horizontal support parts 26 are provided,
One horizontal support portion 26 abuts against one end of the pair of vertical support portions 25,
The electrical storage element (A) in which the other horizontal support part 26 abuts against the other end part of the said pair of vertical support parts 25. The method of claim 7, wherein
The positive electrode foil 7 has an exposed portion exposed from one end of the roll body, and an end portion 7A of the exposed portion is electrically connected to the positive current collector 2,
The negative electrode foil 8 has an exposed portion exposed from one end of the roll body, and an end portion 8A of the exposed portion is electrically connected to the current collector 3 of the negative portion.
The electrical storage element (A) in which said vertical support part (25) is arrange | positioned in the vertical gap part (Ts) between the said two exposed parts and the said case (4). 9. The method of claim 8,
The electrical storage element (A) in which the support member (13) which has the said vertical support part (25) and the said horizontal support part (26) is provided between the said roll bodies. 10. The method according to any one of claims 1 to 9,
The electrical storage element (A) whose said support member 13 is a synthetic resin material. 10. The method according to any one of claims 1 to 9,
The insulating bag 27 which is arrange | positioned between the said electrode body 1 and the said electrical power collectors 2 and 3 and the said case 4, and accommodates these electrode bodies 1 and electrical power collectors 2 and 3 is further provided. I have it,
The electrical storage element (A) in which the said support member (13) and the said insulating bag (27) are formed integrally. As an insulating bag 27 provided in the electrical storage element A of Claim 1,
It is disposed between the electrode body 1 and the current collectors 2 and 3 and the case 4 to accommodate these electrode bodies 1 and the current collectors 2 and 3,
An insulating bag (27) formed integrally with the support member (13).

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