The present invention relates to a square secondary battery.
In recent years, large-capacity (Wh) secondary batteries have been developed as power sources of hybrid electric vehicles or pure electric vehicles and among others, square lithium ion secondary batteries with a high energy density (Wh/kg) have attracted attention.
In a square lithium ion secondary battery, a flat wound electrode group is formed as a power generation element by stacking up and winding a positive electrode in which positive electrode foil is coated with a positive electrode active material, a negative electrode in which negative electrode foil is coated with a negative electrode active material, and a separator to insulate the positive electrode and the negative electrode. The wound electrode group is electrically connected to a positive electrode external terminal and a negative electrode external terminal provided on a battery lid of a battery container. The wound electrode group is housed in a battery can of the battery container and an opening of the battery can is sealed with the battery lid and welded. A square secondary battery is formed by injecting an electrolytic solution through an injection hole of the battery container and then blocking off the injected solution by an injection tap and sealing by laser welding.
A battery module is formed by electrically connecting the positive electrode external terminal and the negative electrode external terminal of a plurality of square secondary batteries using a conductive member such as a bus bar. The bus bar is connected to the square secondary battery by being screwed onto an external terminal using a bolt and a nut or welded to the external terminal.
In PTL 1, an external terminal connecting a plurality of secondary batteries and formed from a clad material made of aluminum and nickel and a connection terminal (electrode led pin in PTL 1) made of aluminum from inside the secondary battery are provided. The secondary battery described in PTL 1 is fixed by caulking to the connection terminal joined with a power generation element on the nickel side of the external terminal.
In PTL 2, a plurality of square secondary batteries is connected by a bus bar being welded to the external terminals, each external terminal to be connected is made of an alloy of aluminum and copper, and the bus bar includes a clad material in which an aluminum alloy and a copper alloy are joined as dissimilar metals. The bus bar described in PTL 2 has an aluminum alloy and a copper alloy are butt-joined on narrow-width surfaces and the aluminum alloy of the bus bar and the connection terminal made of the aluminum alloy are welded to the copper alloy of the bus bar and the connection terminal made of the copper alloy for connection.
PTL 1: JP 2003-045408 A
PTL 2: JP 2011-060623 A
The secondary battery described in PTL 1 is electrically connected to the connection terminal joined with the power generation element and made of the aluminum alloy by caulked fixing on the nickel side of the clad external terminal in which dissimilar metals of the aluminum alloy and nickel change and therefore, the contact resistance is large and may change over a long period of time.
The secondary battery described in PTL 2 is a secondary battery in which the bus bar is connected to the external terminal by welding and includes the external terminal made of the aluminum alloy and copper alloy and the bus bar to connect to another secondary battery is a clad bus bar in which dissimilar metals of the aluminum alloy and copper alloy in a flat plate shape are changed on narrow width surfaces (end faces are clad-joined) and therefore, the junction resistance of a dissimilar metal change portion of the aluminum alloy and copper alloy could become large.
The present invention is made in view of the above circumstances and an object thereof is to provide a square secondary battery whose external terminal is formed in a simple structure and capable of reducing the contact resistance of joints of a connection terminal and the external terminal and the junction resistance of a dissimilar metal change portion of the external terminal.
A square secondary battery to solve the above problem includes a power generation element including electrodes, a can housing the power generation element, a lid sealing an opening of the can, an external terminal arranged on the lid, a current collector connected to the electrodes of the power generation element, and a connection terminal connecting the current collector and the external terminal by passing through the lid, wherein the external terminal has a flat plate shape arranged along the lid and is made of a clad material in which two flat plate portions made of mutually dissimilar metals are clad-joined on wide-width surfaces and the connection terminal is joined by welding with, of the two flat plate portions of the external terminal, the flat plate portion arranged on a side of the lid.
Advantageous Effects of Invention
According to the present invention, a square secondary battery whose external terminal is formed in a simple structure and capable of reducing the contact resistance of a connection terminal and the external terminal made of a clad material and the junction resistance of a dissimilar metal change portion of the external terminal made of the clad material can be provided.
Hereinafter, an embodiment of the square secondary battery according to the present invention will be described with reference to the drawings.
As shown in
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As shown in
The battery lid 102 is provided with a gas exhaust valve 103. The gas exhaust valve 103 is formed by partially thinning the battery lid 102 by press working. Incidentally, a thin-film member may be mounted in an opening of the battery lid 102 to use a thin portion as the gas exhaust valve. The gas exhaust valve 103 reduces the pressure inside the battery container by cleaving when the pressure inside the battery container rises and reaches a predetermined pressure after the square secondary battery 100 is heated due to an abnormal condition such as an internal short-circuit and a gas is generated and allowing the gas to be exhausted from inside.
The wound electrode group 170 will be described with reference to
The positive electrode 174 is produced by forming a layer 176 of a positive electrode active material mixture on both sides of positive electrode foil 171. The positive electrode active material mixture is prepared by adding a binder to a positive electrode active material. The negative electrode 175 is produced by forming a layer 177 of a negative electrode active material mixture on both sides of negative electrode foil 172. The negative electrode active material mixture is prepared by adding a binder to a negative electrode active material.
The positive electrode foil 171 is aluminum foil of about 20 to 30 pm in thickness and the negative electrode foil 172 is copper foil of about 15 to 20 pm in thickness. The raw material of the separators 173a, 173b is a fine porous polyethylene resin through which lithium ions can pass. The positive electrode active material is lithium containing transition metal composite oxide such as lithium manganate and the negative electrode active material is a carbon material such as graphite capable of reversibly occluding and releasing lithium ions.
One of both ends in the width direction of the wound electrode group 170, that is, one of both ends in a direction of a winding central axis W perpendicular to the winding direction is a laminated portion of the positive electrode 174 and the other is a laminated portion of the negative electrode 175. The laminated portion of the positive electrode 174 provided on one end is formed by laminating a positive electrode non-coated portion where the positive electrode active material mixture layer 176 is not formed, that is, an exposed portion of the positive electrode foil 171. The laminated portion of the negative electrode 175 provided on the other end is formed by laminating a negative electrode non-coated portion where the negative electrode active material mixture layer 177 is not formed, that is, an exposed portion of the negative electrode foil 172. The laminated portion of the positive electrode non-coated portion and the laminated portion of the negative electrode non-coated portion are each crushed in advance and connected to the positive electrode current collector 180 and the negative electrode current collector 190 of the lid assembly 107 (see
The configuration of the lid assembly 107 will be described in detail with reference to
As shown in
A negative electrode external terminal joint 105c to connect the negative electrode connection terminal 115 is provided in the center position in the longitudinal direction of the copper alloy portion 105b of the negative electrode external terminal 105. The negative electrode external terminal joint 105c is formed by being recessed in the copper alloy portion 105b and constituted by a circular recess having a fixed diameter and a predetermined depth.
The negative electrode connection terminal 115 is laser-welded while an end face thereof is fitted into the negative electrode external terminal joint 105c. The negative electrode connection terminal 115 includes the insertion shaft portion 115a in a round bar shape, a flange portion 115c whose diameter is expanded on the end face of the insertion shaft portion 115a, and the tip portion 115b in a cylindrical shape whose diameter is reduced at the tip of the insertion shaft portion 115a. The negative electrode external terminal joint 105c has a depth half the thickness of the flange portion 115c and a hole diameter in which the inner circumferential surface thereof faces the outer circumferential surface of the flange portion 115c. The negative electrode connection terminal 115 and the negative electrode external terminal 105 are mutually joined by the flange portion 115c of the negative electrode connection terminal 115 being fitted into the negative electrode external terminal joint 105c of the negative electrode external terminal 105 and a boundary portion of the outer circumferential surface of the flange portion 115c and the inner circumferential surface of the negative electrode external terminal joint 105c being laser-welded continuously all around the circumference. Then, a welded portion 115d is formed in the joined portion (see
The negative electrode external terminal 105 has a pair of concave grooves 105h extending in a short-side direction in both side positions in the longitudinal direction of the negative electrode external terminal joint 105c of the copper alloy portion 105b. The pair of concave grooves 105h is provided in a position between a welding portion (not shown) where the bus bar 123 is welded to the bus bar joint surface 105e of the negative electrode external terminal 105 and the negative electrode external terminal joint 105c and when a force acts on the negative electrode external terminal 105 from the bus bar 123 (see
The gasket 169 includes a cylindrical portion 169a of a minor axis fitted into the insertion shaft portion 115a of the negative electrode connection terminal 115 at the outside thereof and a collar portion 169b expanding in a radial direction in an end face portion of the cylindrical portion 169a.
Next,
The material of the external insulator 160 and the internal insulator 165 is a resin having insulating properties such as polypropylene (PP). The material of the gasket 169 is a resin having insulating properties such as tetrafluoroethylene-perfluoroalkylvinyl ether copolymer (PFA).
Two convex portions 102j to form seal points with the gasket 169 are provided on the top surface of the battery lid 102. The two convex portions 102j are provided in positions opposite to the collar portion 169b of the gasket 169 and have a circumferentially continuous shape around the same position as the center of the respective through holes 102h. Seal points are formed by the collar portions 169b of the gasket 169 being pressed against the two convex portions for sealing.
As shown in
The positive electrode external terminal 104 has a pair of concave grooves 104h extending in a short-side direction in both side positions in the longitudinal direction of the positive electrode connection terminal 114. The pair of concave grooves 104h is provided in a position between a welding portion (not shown) where the bus bar 123 is welded to the bus bar joint surface 104e of the positive electrode external terminal 104 and the positive electrode connection terminal 114 and when a force acts on the positive electrode external terminal 104 from the bus bar 123 (see
For the electrical connection of the positive electrode external terminal 104 and the positive electrode connection terminal 114, the insertion shaft portion 114a of the positive electrode connection terminal 114 is inserted into an insertion hole opened in the bearing surface portion 181 of the positive electrode current collector 180 and the tip portion 114b protruding from the insertion hole is expanded in diameter to form a caulking portion 114e. Then, the caulking portion 114e is further laser-welded (not shown) to the bearing surface portion 181 to electrically connect the positive electrode external terminal 104 and the positive electrode connection terminal 114 to the positive electrode current collector 180. The positive electrode connection terminal 114 is mounted on the battery lid 102 via the external insulator 160 and the gasket 169. The positive electrode current collector 180 is mounted on the battery lid 102 via the internal insulator 165. The material of the external insulator 160 and the internal insulator 165 is a resin having insulating properties such as polypropylene (PP). The material of the gasket 169 is a resin having insulating properties such as tetrafluoroethylene-perfluoroalkylvinyl ether copolymer (PFA).
The caulking process will be described with reference to
In the caulking process, as shown in
The mold 20 of the caulking device is provided with a protrusion 21 in a pin shape and by inserting the protrusion 21 into a through hole 105f opened in the bus bar joint surface 105e to fit into a recess 154 formed on the end face surface of the negative electrode connection terminal 115, the negative electrode external terminal 105 and the negative electrode connection terminal 115 can be positioned easily and precisely with respect to the caulking device. Thus, the mold 22 with the tip in a conical shape of the caulking device can be pressed into the caulking hole 115f of the tip portion 115b in a cylindrical shape with precision.
The type of the mold 22 with the tip in a conical shape is sequentially replaced with one having a larger tip angle and pressed into the caulking hole 115f of the tip portion 115b to gradually widen the tip portion 115b to the outer side. As shown in
The square secondary battery 100 is connected to another square secondary battery (not shown) by the bus bar 123 to constitute a battery module. In the present embodiment, the bus bar 123 indicated by an alternate long and two short dashes line in
As described above, the negative electrode external terminal 105 has the negative electrode external terminal joint 105c made of a recess in the copper alloy portion 105b on the undersurface side thereof and the flange portion 115c of the negative electrode connection terminal 115 is fitted thereinto. The depth of the negative electrode external terminal joint 105c is shallower than the thickness width of the flange portion 115c of the negative electrode connection terminal 115 and the end face side of the flange portion 115c is fitted into the negative electrode external terminal joint 105c so that the tip side of the flange portion 115c protrudes from the copper alloy portion 105b.
Then, fillet welding is performed by irradiating a boundary portion between the outer circumferential surface of the flange portion 115c and the undersurface of the copper alloy portion 105b with a laser beam for laser welding from an oblique direction to form the welded portion 115d.
The welded portion 115d is arranged in a position on the outer side in the radial direction of the negative electrode connection terminal 115 from the seal point of the gasket 169. Then, the external insulator 160 is arranged in a position further on the outer side in the radial direction from the welded portion 155d. Therefore, a leak path can be prevented from being formed between the top surface of the battery lid 102 and the collar portion 169b of the gasket 169 so that a high level of airtightness can be obtained.
According to the welded fixing configuration described above, the end face side of the flange portion 115c is fitted into the negative electrode external terminal joint 105c and thus, if, for example, a force in a flat surface direction acts on the negative electrode external terminal 105 due to the bus bar 123, the force can be resisted and a high level of mechanical strength can be obtained.
The negative electrode external terminal 105 has a substantially rectangular shape in plan view extending in a direction moving away from the negative electrode connection terminal 115 and thus, the bus bar 123 that is wider can be joined. Therefore, the location where the bus bar 123 is welded can be separated from the negative electrode connection terminal 115 and the gasket 169 can be prevented from being affected by heat of welding. Then, when a battery module is formed, the distance between neighboring square secondary batteries can be shortened and the electric resistance thereof can be reduced. When, for example, a force acts in a direction vertically lifting the negative electrode external terminal 105 by the bus bar 123, the distance from the negative electrode connection terminal 115 to the location where the bus bar 123 is welded on the bus bar joint surface 105e can be secured longer with respect to the amount of deformation of the negative electrode external terminal 105.
In the structure example shown in
The negative electrode external terminal 105 has the negative electrode external terminal joint 105c made of a recess in the copper alloy portion 105b on the undersurface side thereof and the flange portion 115c of the negative electrode connection terminal 115 is fitted thereinto. The depth of the negative electrode external terminal joint 105c is the same as the thickness width of the flange portion 115c of the negative electrode connection terminal 115 and the flange portion 115c and the copper alloy portion 105b are flush with each other while the flange portion 115c is fitted into the negative electrode external terminal joint 105c and fixed.
Then, groove welding is performed by irradiating a boundary portion between the outer circumferential surface of the flange portion 115c and the inner circumferential surface of the negative electrode external terminal joint 105c with a laser beam for laser welding in a direction parallel to an axial direction of the insertion shaft portion 115a to form a welded portion 115h.
The battery lid 102 is provided with the two convex portions 102j to form a seal point facing the gasket 169. The two convex portions 102j are provided in positions opposite to the collar portion 169b of the gasket 169 and have a circumferentially continuous shape around the same position as the center of the respective through holes 102h. Seal points are formed by the collar portions 169b of the gasket 169 being pressed against the two convex portions for sealing.
The welded portion 115d is arranged in a position on the outer side in the radial direction moving away from the insertion shaft portion 115a of the negative electrode connection terminal 115 from the seal point of the gasket 169. Then, the external insulator 160 is arranged in a position further on the outer side in the radial direction from the welded portion 155d. Therefore, a leak path can be prevented from being formed between the top surface of the battery lid 102 and the collar portion 169b of the gasket 169 so that a high level of airtightness can be obtained.
In the structure example shown in
In the first embodiment described above, the configuration in which the negative electrode external terminal 105 and the negative electrode connection terminal 115 are integrated by laser welding is taken as an example, but the negative electrode external terminal 105 and the negative electrode connection terminal 115 may be fixed by caulking and further laser-welded.
The negative electrode connection terminal 115 has the end face portion 115g inserted into the through hole 105g of the negative electrode external terminal 105. Then, like the caulking process shown in
According to the present embodiment described above, the operation/working effect as described below can be achieved.
According to the present invention, a square secondary battery whose external terminal is formed in a simple structure and which reduces the connection resistance of a connection terminal and the external terminal made of a clad material and the connection resistance of the dissimilar metal change portion of the external terminal made of the clad material can be provided.
Insofar as features of the present invention are not spoiled, the present invention is not limited to the above embodiments and other forms conceived within the scope of technical ideas of the present invention are included in the scope of the present invention.
In the above embodiments, for example, a case when a clad material made of the aluminum alloy portion 105a and the copper alloy portion 105b is used for the negative electrode external terminal 105 and the bus bar 123 made of an aluminum alloy is connected is taken as an example, but, for example, a structure in which the negative electrode external terminal 105 is formed from a copper alloy, a clad material made of a copper alloy portion and an aluminum alloy portion is used for the positive electrode external terminal 104, and a bus bar made of the copper alloy is connected may also be adopted.
The seal point is preferably provided in at least one case of between the gasket 169 and the battery lid 102 and between the gasket 169 and the negative electrode connection terminal 115 and may also be provided in both cases.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/079008 | 10/25/2013 | WO | 00 |