This application claims priority to, and the benefit of, Korean Patent Application No. 10-2013-0099715 filed in the Korean Intellectual Property Office on Aug. 22, 2013, the entire contents of which are incorporated herein by reference.
1. Field
The described technology relates generally to a pouch type rechargeable battery with a sealing portion of a pouch and a terrace portion insulated by an insulation tape.
2. Description of the Related Technology
With the development of mobile devices, demand for rechargeable batteries as an energy source has increased. In addition, high-energy, down-sized, light, and slim mobile devices are desired. For example, a rechargeable battery is flatly formed using a polymer solid electrolyte film. As the rechargeable battery, there is a pouch-type battery effectively implementing the slimness of the battery.
The pouch type rechargeable battery typically has a pouch sealing portion that is insulated by an insulation tape and adhered to a side of a cell body. Also, the pouch type rechargeable battery forms a terrace from a side of a lead tab draw out of the cell body to the sealing portion of the pouch. The lead tab is insulated from the terrace by interposing a tab seal.
The above information disclosed in this Background section is only for enhancement of understanding of the background of the described technology and therefore it may contain information that does not form the prior art that is already known in this country to a person of ordinary skill in the art.
Embodiments provide a pouch type rechargeable battery with an insulated terrace side end (a metal portion) and tightly adhering an insulation tape by adhering the insulation tape while absorbing a position tolerance of a lead tab (or a tab seal) on a terrace.
A pouch type rechargeable battery according to an embodiment includes: an electrode assembly; a pouch forming a sealing portion at a side surface of a cell body receiving the electrode assembly by sealing an outer portion thereof, forming a terrace at the other side surface of the cell body, and sealing a lead tab connected to the electrode assembly by a tab seal to draw it out to the terrace; and an insulation tape configured to insulate the sealing portion to be adhered to the cell body and insulating the terrace, wherein the insulation tape includes a cutting portion corresponding to one side of the tab seal and adhered to the tab seal.
The terrace may include a bottom portion connected to a bottom of the cell body, and a side wall portion bent at the bottom portion and connected to the sealing portion adhered to a side surface of the cell body.
The insulation tape may also include a first portion insulating a side end of the sealing portion and a side end of the side wall portion, and a second portion connected vertically to the first portion and insulating the side end of the bottom portion and the other side end of the side wall portion.
A first center line of the first portion may accord with the side end of the sealing portion, a second center line of the second portion may accord with the side end of the bottom portion, and a cross point where the first center line and the second center line cross with a vertex of the side wall portion.
The cutting portion may be cut according to the second center line at one side of the second center line.
A length of the cutting portion may be about 1 to 2 times a position tolerance range of the tab seal.
The position tolerance range of the tab seal may be about ±0.7 mm, and the length of the cutting portion may be about 1 to 1.4 mm.
The insulation tape may be firstly bent to insulate the side end of the sealing portion and one side end of the side wall portion by the first portion, and may be secondly bent to insulate the side end of the bottom portion and the other side end of the side wall portion by the second portion.
The second portion may dispose the cutting portion by corresponding to the tab seal, and both sides of the cutting portion are adhered to both surfaces of the tab seal.
The end of the cutting portion may be positioned between the lead tab and the tab seal.
As described above, according to an embodiment, the position tolerance of the lead tab (or the tab seal) is absorbed by the cutting portion of the insulation tape on the terrace and adheres the insulation tape such that the terrace side end (the metal portion) may be insulated and the insulation tape may be tightly adhered.
The present invention will be described more fully hereinafter with reference to the accompanying drawings, in which certain embodiments of the invention are shown. As those skilled in the art would realize, the described embodiments may be modified in various ways, without departing from the spirit or scope of the present invention. The drawings and description are to be regarded as illustrative in nature and not restrictive. Like reference numerals generally designate like elements throughout the specification.
In pouch type rechargeable batteries, an insulation tape typically insulates a side end of the terrace to prevent a short circuit of the side end (an exposed portion of a metal) of the terrace. The lead tab and the tab seal have a position tolerance on the terrace. Accordingly, the side end of the terrace may be exposed between the sides of the insulation tape and the lead tab (or the tab seal) insulating the side end of the terrace, and adhesion performance of the insulation tape may be deteriorated by interference of the insulation tape and the tab seal.
Referring to
The electrode assembly 10 is formed in a jelly-roll shape by winding a first electrode (for convenience, referred to as a positive electrode) 11 and a second electrode (for convenience, referred to as a negative electrode) 12, interposing a separator 13 therebetween. The separator 13 may be made of a polymer solid electrolyte film through which lithium ions may pass.
The positive electrode 11 includes a coated region obtained by coating an active material on a thin film current collector, and an uncoated region set as a collector that is exposed because of not being coated with the active material. A first lead tab (for convenience, referred to as a positive electrode lead tab) 14 is connected to the uncoated region of the positive electrode 11 to extend therefrom.
The negative electrode 12 includes a coated region obtained by coating an active material that is different from that of the positive electrode 11 on a thin film current collector, and an uncoated region set as a collector that is exposed because of not being coated with the active material. A second lead tab (for convenience, referred to as a negative electrode lead tab) 15 is connected to the uncoated region of the negative electrode 12 from the opposite side of the positive lead tab 14 to extend therefrom.
The electrode assembly 10 is substantially formed of a plane plate structure with a cuboidal shape such that the cell body 211 receiving the electrode assembly 10 is substantially formed of a plane plate structure of the cuboidal shape. The rechargeable battery encloses the electrode assembly 10 by the pouch 20 thereby entirely forming a plane plate structure of the cuboidal shape.
The sealing portion 212 is formed at a side surface (for example, a second side surface of a long edge) of the cell body 211 to be adhered to the side surface of the cell body 211. The terrace 213 is formed at the other side surface (for example, a first side surface of a short edge) of the cell body 211 to draw out the positive electrode lead tab 14 and the negative electrode lead tab 15 connected to the electrode assembly 10 to the outside.
The positive electrode lead tab 14 and the negative electrode lead tab 15 are electrically insulated from the terrace 213 by respectively interposing tab seals 18 and 19. The tab seals 18 and 19 are protruded further than the terrace 213 (in the x-axis direction) and may protrude in a width direction (the y-axis direction) of the positive and negative electrode lead tabs 14 and 15.
The pouch 20 may be formed in a multi-layered sheet structure that receives and seals the electrode assembly 10. For example, in a deposition direction, the pouch 20 includes a polymer sheet 21, a metal sheet 23, and a nylon sheet 22.
The polymer sheet 21 constitutes an inner surface of the pouch 20 and performs insulation and thermal fusion-bonding functions, and the nylon sheet 22 constitutes an outer surface of the pouch 20 and performs a protection function. The nylon sheet 22 may be replaced by a PET (polyethylene terephthalate) sheet, a nylon sheet, or a PET-nylon composite sheet. The metal sheet 23 provides mechanical strength and may be formed of an aluminum sheet as one example. The insulation tape 30 is adhered to the sealing portion 212 and the terrace portion 213 of the pouch 20 to insulate the side end of the metal sheet 23.
Also, in an aspect of receiving the electrode assembly 10, the pouch 20 includes a first exterior member 201 and a second exterior member 202. The first and second exterior members 201 and 202 may be formed of the polymer sheet 21, the nylon sheet 22, and the metal sheet 23 having the same structure.
The first exterior member 201 is formed of a concave structure to receive the electrode assembly 10, and the second exterior member 201 is formed of a plane structure to cover the electrode assembly 10. Also, the first and second exterior members 201 and 202 are thermal-fused at the outside receiving the electrode assembly 10 thereby forming the sealing portion 212.
The sealing portion 212 is formed by thermal-fusing the first exterior member 201 that is bent according to the electrode assembly 10 to a plane bottom surface of the second exterior member 202. The sealing portion 212 is bent from both sides of the y-axis direction into the z-axis direction and is adhered to a side surface of the cell body 211 such that the terrace 213 is formed at one side of the x-axis direction.
The insulation tape 30 insulates the sealing portion 212 and is adhered to the side surface of the cell body 211. Also, the insulation tape 30 insulates one side of the terrace 213 and the tab seals 18 and 19.
For convenience, one side of the tab seal 18 will be described. The insulation tape 30 includes a cutting portion 33 corresponding to one side of the tab seal 18, thereby being connected to the terrace 213 and the tab seal 18. Accordingly, a side end 311 of a bottom portion 131 may be insulated by the insulation tape 30 at one side of the tab seal 18.
For example, the terrace 213 includes the bottom portion 131 connected to a bottom of the cell body 211 and a side wall portion 132 bent from the bottom portion 131 and connected to the sealing portion 212 adhered to the side surface of the cell body 211. A portion of the side end 311 of the terrace 213 is included in the bottom portion 131 and the remaining portion 321 is included in the side wall portion 132.
Accordingly, the insulation tape 30 insulates the side end 311 of the bottom portion 131 and both side ends 321 and 322 of the side wall portion 132 in the side direction of the positive and negative electrode lead tabs 14 and 15. For example, both side ends 321 and 322 may be formed to be perpendicular to each other.
For example, the insulation tape 30 includes a first portion 31 adhered to the sealing portion 212 for insulating and a second portion 32 vertically connected to the first portion 31 and adhered to both surfaces of the bottom portion 131 for insulating.
The first portion 31 insulates both surfaces at the sealing portion 212, thereby insulating the side end 121 of the sealing portion 212 and the side end 322 of the side wall portion 132. A first center line CL1 of the first portion 31 accords with the side end 121 of the sealing portion 212 and the side end 322 of the side wall portion 132.
The second portion 32 insulates both surfaces at the bottom portion 131 thereby insulating the side end 311 of the bottom portion 131 and the side end 321 of the side wall portion 132. A second center line CL2 of the second portion 32 accords with the side end 311 of the bottom portion 131 and the side end 321 of the side wall portion 132.
A cross point P of the first center line CL1 and the second center line CL2 accords with a vertex of the side wall portion 132. The cross point P accords with a point where the side end 321 and the side end 322 of the side wall portion 132 are connected.
Accordingly, in the terrace 213, both side ends 322 and 321 of the side wall portion 132 are insulated by the first and second portions 31 and 32 of the insulation tape 30. The first center line CL1 accords with a center of a short check hole H30. The side end 121 of the sealing portion 212 and the side end 322 of the side wall portion 132 are partially exposed through the short check hole H30 such that a short check is possible.
If the electrode assembly 10 is installed in the pouch 20 and is sealed, the positive and negative electrode lead tabs 14 and 15 may have a position tolerance at the bottom portion 231. The positive and negative electrode lead tabs 14 and 15 are insulated by the tab seals 18 and 19 and are drawn out such that the tab seals 18 and 19 may have substantial position tolerance at the bottom portion 231.
A distance determined between the positive and negative electrode lead tabs 14 and 15 and the side wall portion 232 includes the tolerance. Substantially, a distance determined between the tab seal 18 and 19 and the side wall portion 232 includes the tolerance.
To absorb the tolerance, the insulation tape 30 includes the cutting portion 33. For example, the cutting portion 33 is formed by cutting the second portion 32 according to the second center line CL2 at one side on the second center line CL2.
One side of the tab seal 18 is received to the cutting portion 33, and the opened second portion 32 is adhered to both surfaces of the tab sealing member 18. One side of the second portion 32 is opened at the cutting portion 33 such that one side may deviate from the tab seal 18 and may be again adhered on the tab seal 18. Accordingly, between the tab seal 18 and the side wall portion 132, the side end 311 of the bottom portion 131 may be insulated by the second portion 32 of the insulation tape 30.
A length L of the cutting portion 33 may be determined as 1 to 2 times the position tolerance range of the positive and negative electrode lead tabs 14 and 15. The second portion 32 of the insulation tape 30 has the cutting portion 33 corresponding to a minimum tolerance range such that the side end 311 of the bottom portion 131 may be sufficiently insulated between the tab seal 18 and the side wall portion 132.
For example, it may be predetermined that the position tolerance range of the tab seal 18 and 19 is about ±0.7 mm, and the length L of the cutting portion 33 is from about 1 to about 1.4 mm. The second portion 32 may correspond to the cutting portion 33 of the length L of 1 and the minimum tolerance (for example, about −7 mm), and the cutting portion 33 of the length L of about 1.4 mm and the maximum tolerance (for example, about +7 mm).
The second portion 32 is adhered to both surfaces of the tab seal 18 in the entire range of the tolerance, thereby insulating the side end 311 of the bottom portion 131 between the tab seal 18 and the side wall portion 132. The end of the cutting portion 33 is positioned between the positive electrode lead tab 14 and the tab seal 18.
Next, referring to
Referring to
The first portion 31 of the insulation tape 30 is adhered to one surface (a lower surface) of the sealing portion 212 and one surface (a lower surface) of the side wall portion 132, and the vertex of the side wall portion 132 accords with the cross point P. Accordingly, the first portion 31 is disposed in a state of being capable of insulating the side end 121 of the sealing portion 212 and the side end 322 of the side wall portion 132.
The second portion 32 of the insulation tape 30 is adhered to one surface of the bottom portion 131 and one surface of the side wall portion 132, and a vertex of the side wall portion 132 accords with the cross point P.
The cutting portion 33 corresponds to the tab seal 18, and the second portion 32 of one side of the cutting portion 33 is adhered to the lower surface of the bottom portion 131. The end of the y-axis direction of the cutting portion 33 is positioned between the positive electrode lead tab 14 and the tab seal 18. Accordingly, the second portion 32 insulates the side end 311 of the bottom portion 131 and the side end 311 of the side wall portion 132, and the tolerance portion of the side end may be further insulated.
The first portion 31 of the insulation tape 30 insulates the side end 121 of the sealing portion 212 and the side end 322 of the side wall portion 132.
Also, one side of the second portion 32 of the insulation tape 30 is adhered to the tab seal 18 and one surface (a lower surface) of the bottom portion 131 corresponding thereto with reference to the cutting portion 33, and the other side thereof is adhered to the tab seal 18 and the other surface (an upper surface) of the bottom portion 131 corresponding thereto. The end of the y-axis direction of the cutting portion 33 is positioned and adhered between the positive electrode lead tab 14 and the tab seal 18.
The second portion 32 near the cutting portion 33 may completely insulate the side end 311 of the bottom portion 131 at one side of the tab seal 18 in spite of the position tolerance of the tab seal 18. Accordingly, the insulation deterioration may be prevented in one side of the tab seal 18 of the bottom portion 131.
Also, if the sealing portion 212 adhered with the first portion 31 is thirdly bent (in a direction F3 of
While this invention has been described in connection with certain embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.
Number | Date | Country | Kind |
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10-2013-0099715 | Aug 2013 | KR | national |