JP2001210286A - Packed battery - Google Patents

Abstract

PROBLEM TO BE SOLVED: To effectively radiate heat from internal secondary batteries from which heat is not easily dissipated, without making hot a case heated to a high temperature while effectively radiating heat from the built-in batteries. SOLUTION: A packed battery comprises a plurality of secondary batteries 1 and a case 2 for storing the plurality of secondary batteries 1. The case 2 has a pair of both-face plates 2A arranged on both faces and side-face plates 2B for connecting the both-face plates 2A at their sides. The both-face plates 2A have plane portions allowing hand carriage and are formed of plastics to be wider than the side plates 2B. On the other hand, the side plates 2B formed of metal plates are constructed to effectively radiate heat from the secondary batteries 1.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a battery pack having a plurality of secondary batteries built in a case. In particular, the present invention relates to a battery pack that is optimal for applications charged and discharged with a large current.

[0002]

2. Description of the Related Art In a battery pack charged and discharged with a large current, the case may become hot. In particular, if the battery is discharged with a large current and then immediately charged with a large current without a break, the case of the battery pack may become extremely hot. In this state, when the user removes the fully charged battery from the charger, there is a problem that the user feels hot by touching the battery heated to a high temperature. This adverse effect can be solved by delaying the display of the full charge of the battery pack until the battery temperature decreases and displaying the battery pack. That is, it is possible to solve the problem by displaying a full charge by providing a delay time for cooling the battery without displaying the full charge when the fully charged charge is stopped.

[0003]

However, in this method, the battery pack is fully charged in a short time,
There is an adverse effect of delaying the actual use time. In particular,
A battery pack used as a power source of a power tool or the like used with a large current may be used immediately after being fully charged after being fully charged. For this reason, the battery is rapidly charged with a large current of 1 C or more so that the battery can be reused by charging as short as possible. Nevertheless, if the delay time is provided after the full charge, the advantage of rapidly charging the battery in the extremely reduced state cannot be utilized.

[0004] Further, when the battery is charged, the battery temperature tends to further increase after the battery is fully charged and the current is interrupted, as shown in FIG. This means
Prolong the time to cool the battery. Therefore, the battery temperature cannot be reduced with a short delay time. Therefore, it is necessary to increase the delay time to cool the battery,
There is a disadvantage that a fully charged battery cannot be reused immediately.

The surface temperature of a battery pack can be reduced by coating the surface with a thick plastic. However, a thick film significantly deteriorates the heat radiation characteristics of the battery. For this reason, the temperature of the charged battery rises abnormally, which significantly reduces the performance of the battery. In order not to lower the electric performance of the battery, it is extremely important how effectively the heat generated from the battery can be radiated. However, the structure for effectively dissipating the heat of the battery is a structure for increasing the surface temperature of the battery pack, and it is extremely difficult to satisfy both characteristics.

A first object of the present invention is to satisfy characteristics that are mutually contradictory and that are extremely difficult to realize both. That is, an important object of the present invention is to provide a battery pack that can hold a case heated to a high temperature without feeling hot while effectively dissipating heat in a built-in battery.

[0007] Further, a battery pack used for charging / discharging with a large current is used for electric equipment which requires a large output, and therefore contains a large number of secondary batteries. When a battery pack containing a large number of secondary batteries is charged and discharged with a large current, it becomes extremely difficult for the internal secondary batteries to dissipate heat. A second object of the present invention is to provide a battery pack that contains a plurality of secondary batteries and is difficult to effectively radiate heat and that can effectively radiate the internal secondary batteries.

[0008]

According to a first aspect of the present invention, a battery pack includes a plurality of rechargeable batteries and a case containing the rechargeable batteries. The case 2 includes a pair of double-sided plates 2A disposed on both sides and a side plate 2B connecting both sides of the double-sided plate 2A. The double-sided plate 2A has a flat portion so that it can be held by hand, and is formed of plastic in a shape wider than the side plate 2B. On the other hand, the side plate 2B is formed of a metal plate and has a structure capable of effectively radiating heat of the secondary battery 1.

Further, in the battery pack according to the second aspect of the present invention, in addition to the plurality of secondary batteries 1 and the case 2 accommodating these secondary batteries 1, a conductive metal plate 3 is provided in the case 2. Is arranged. Case 2 includes a plurality of rechargeable batteries 1
Are arranged in three or more rows and stored. A conductive metal plate 3 is provided along the surface of the secondary batteries 1 arranged in the middle row. The conductive metal plate 3 is extended to the side surface of the case 2 to effectively conduct the heat of the secondary battery 1 in the middle row to the side of the case 2 and dissipate the heat.

In the battery pack, the secondary batteries 1 are preferably housed in the case 2 in three rows. A conductive metal plate 3 formed in a waveform along the surface of the secondary battery 1 is provided on both side surfaces of the secondary batteries 1 arranged in the intermediate row. The conductive metal plate 3 is extended to the side of the case 2,
The heat of the secondary battery 1 in the middle row is radiated to the outside.

A battery pack in which the secondary batteries 1 are accommodated in three rows in the case 2 has a number of secondary batteries 1 arranged in an intermediate row.
The number of the secondary batteries 1 arranged in the outer row is increased by one, and the secondary batteries 1 in the outer row are arranged between the valleys of the secondary batteries 1 arranged in the intermediate row.

Further, in the battery pack according to the fifth aspect of the present invention, there are provided a plurality of secondary batteries 1, a case 2 accommodating these secondary batteries 1, and a conductive member disposed in the case 2. And a metal plate 3. The case 2 includes a pair of double-sided plates 2A disposed on both sides, and a side plate 2B connecting both sides of the double-sided plate 2A. The double-sided plate 2A has a flat portion and is formed of plastic in a shape wider than the double-sided plate 2A. The side plate 2B is formed of a metal plate.

Further, in this battery pack, a plurality of rechargeable batteries 1 are arranged in a plurality of rows of three or more rows and housed in a case 2, and a conductive metal plate is formed along the surface of the rechargeable batteries 1 arranged in an intermediate row. 3 are arranged. Conductive metal plate 3
Are thermally coupled to the side plate 2B and efficiently radiate the conducted heat to the outside from the side plate 2B.

[0014]

Embodiments of the present invention will be described below with reference to the drawings. However, the embodiments described below illustrate a battery pack for embodying the technical idea of the present invention, and the present invention does not specify the battery pack as follows.

Further, in this specification, in order to make it easier to understand the claims, the numbers corresponding to the members shown in the embodiments will be referred to as “claims” and “ In the column of “means”.
However, the members described in the claims are not limited to the members of the embodiments.

The battery pack shown in FIGS. 2 and 3 is used for electric tools and assisted bicycles, but the battery pack of the present invention is not limited to the above-mentioned applications. The battery pack shown in FIG. 2 includes a plurality of secondary batteries 1 and a case 2 accommodating the secondary batteries 1. The battery pack shown in FIG. 3 includes a plurality of secondary batteries 1 and a case 2 accommodating the secondary batteries 1 and a conductive metal plate along the surface of the secondary batteries 1 arranged in an intermediate row. 3 are arranged.

The secondary battery 1 is a nickel-cadmium battery or a nickel-hydrogen battery, but a secondary battery such as a lithium ion secondary battery can also be used. In the illustrated battery pack, the secondary battery 1 is a cylindrical battery, but may be a square battery or an elliptical battery.

The battery packs shown in FIGS. 2 and 3 contain cylindrical batteries arranged in three rows. In this battery pack, the number of rechargeable batteries 1 arranged in the middle row is set to be one more than the number of rechargeable batteries 1 arranged in the outer row, and the number of the rechargeable batteries 1 arranged in the middle row is increased. A row of secondary batteries 1 is provided. In this arrangement, the secondary battery 1 is stored in the case 2,
Can be stably held in place. The plurality of secondary batteries 1 housed in the case 2 are connected in series or in parallel to each other, and are connected to an output terminal (not shown) provided in the case 2.

The case 2 includes a pair of double-sided plates 2A provided on both upper and lower sides in the drawing, and a pair of double-sided plates 2A.
And a side plate 2B connecting both sides thereof. The battery pack is detached from the charger or the electric device by grasping the double-sided plate 2A by hand. The double-sided plate 2A has a substantially flat surface over its entire surface and is bent along both sides along the battery for easy grasping. Further, the double-sided plate 2A has a shape wider than the side plate 2B, and is formed of plastic so that it can be held by hand even when the built-in secondary battery 1 becomes hot. Plastic has a lower thermal conductivity than a metal plate. For this reason, even if the stored battery becomes hot, the surface of the double-sided plate 2A does not become hot.

It is important that the heat of the battery housed in the case 2 be dissipated as effectively as possible. In order to realize this, the case 2 is not entirely formed of plastic. The side plate 2B of the case 2 is formed of a metal plate to more efficiently dissipate the heat of the battery.
In the battery packs shown in FIGS. 2 and 3, since the batteries are housed in three rows, the heat radiation of the batteries in the middle row is deteriorated. Since the batteries in the outer row are in direct contact with the case 2, even if the case is molded of a plastic having low thermal conductivity,
This is because heat is dissipated in direct contact with this.

In the battery packs shown in FIGS. 2 and 3, the outermost battery in the middle row is thermally bonded to the side plate 2B, which is a metal plate, that is, the battery is in a state where heat can be conducted. The battery pack shown in FIG. 3 has the conductive metal plate 3 interposed therebetween, and the battery pack shown in FIG. 2 does not have the conductive metal plate interposed therebetween, and the side plate 2B is curved along the surface of the cylindrical battery. 1 is brought into contact with the surface over a wide area. The battery pack of this structure has a conductive metal plate 3
In addition, the secondary battery 1 contacts the side plate 2B with a large area, and the heat of the battery can be effectively radiated by the side plate 2B.

In particular, as shown in FIGS. 2 and 3, the arrangement in which the batteries in the middle row are larger than the batteries in the outer row and the batteries in the middle row protrude to both sides is such that the side plate 2B is formed of a cylindrical battery. Curved along the surface allows the side plate 2B to contact the middle row of cells or conductive metal plate 3 over a large area.

The side plate 2B and the double-sided plate 2A
The border is wrapped and the wrap is glued and connected. However, when molding a plastic double-sided plate, a side plate, which is a metal plate, can be inserted and connected. In this structure, for example, a through hole is provided in a portion to be inserted into the double-sided plate, so that the double-sided plate and the side plate can be more firmly connected.

The case 2 in which the side plate 2B and the double-sided plate 2A are connected has a cylindrical shape, and a plurality of secondary batteries 1 are housed side by side inside. Both ends of the battery pack are closed by bonding a plastic lid integrally formed with the double-sided plate or a lid manufactured as a separate part from the double-sided plate.

The conductive metal plate 3 built in the battery pack of FIG. 3 radiates heat of the batteries in the middle row more efficiently. The conductive metal plate 3 has a shape in which the metal plate is formed along the surface of the secondary batteries 1 arranged in the middle row, and has both ends extending toward the side surface of the case 2. The conductive metal plate 3 shown in the figure is formed in a waveform along the surface of the cylindrical batteries arranged in the middle row. Further, the conductive metal plate 3 in the figure is thermally coupled by bringing both ends into contact with the side plate 2B. The width of the conductive metal plate 3 is
About the total length of This conductive metal plate 3
The width is wide, and the heat of the batteries in the middle row is most efficiently conducted to the side plate 2B of the case 2. However, the width of the conductive metal plate does not necessarily need to be the entire length of the secondary battery,
It can be shorter than the secondary battery.

The conductive metal plate 3 is a metal plate excellent in heat conduction, for example, a metal plate such as an aluminum plate, a copper plate, and an iron plate. The whole shape is formed into a cylindrical shape, and is disposed on both surfaces of the secondary battery 1 in the middle row.

Conductive metal plate 3 and side plate 2B
Is bonded with an adhesive having excellent heat conduction, so that the heat of the conductive metal plate 3 can be more efficiently conducted to the side plate 2B. Another feature is that by bonding the conductive metal plate 3 and the side plate 2B to each other by bonding, the secondary battery 1 in the middle row accommodated in the case 2 can be held at a fixed position.

[0028]

The battery pack according to the first aspect of the present invention has a feature that the case to be heated to a high temperature can be held without feeling hot while effectively dissipating the built-in battery.
That is, the battery pack of the present invention comprises a case in which a plurality of secondary batteries are built in, a pair of double-sided plates, and a side plate connecting both sides of the double-sided plate. This is because the side plate is a metal plate. The battery pack with this structure can be attached to and detached from a charger or electric device by holding the plastic double-sided plate by hand, so even if the internal battery becomes hot, the temperature of the double-sided plate surface can be lowered, and it can be handled without feeling hot . In addition, the heat of the battery is efficiently radiated by the side plate that is not touched by hand,
Evil effects due to battery heat can be prevented.

Further, the battery pack according to the second aspect of the present invention incorporates a plurality of secondary batteries, and it is extremely difficult to effectively dissipate heat. There are features. That is, this pack battery arranges a plurality of secondary batteries in three or more rows and stores them in a case, and arranges a conductive metal plate along a surface of the secondary batteries arranged in an intermediate row. This is because the conductive metal plate is extended to the side surface of the case to have a structure capable of effectively dissipating heat.

[Brief description of the drawings]

FIG. 1 is a graph showing the relationship between the state of charge of a battery and the surface temperature of the battery.

FIG. 2 is a sectional perspective view of a battery pack according to an embodiment of the present invention.

FIG. 3 is a sectional perspective view of a battery pack according to another embodiment of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Secondary battery 2 ... Case 2A ... Double-sided plate 2
B: Side plate 3: Conductive metal plate

Claims (5)

[Claims] 1. A case (2) comprising a plurality of rechargeable batteries (1) and a case (2) accommodating these rechargeable batteries (1).
Is a pair of double-sided plates (2A) arranged on both sides,
Side plate (2A) connecting both sides of the double-sided plate (2A)
B), the double-sided plate (2A) has a flat portion and is formed of plastic in a shape wider than the side plate (2B), and the side plate (2B) is formed of a metal plate Battery pack. 2. A plurality of secondary batteries (1), a case (2) accommodating these secondary batteries (1), and a conductive metal plate (2) disposed in the case (2). 3), the plurality of secondary batteries (1) are arranged in a plurality of rows of three or more rows, stored in a case (2), and a conductive metal plate is arranged along the surface of the secondary batteries (1) arranged in an intermediate row. (3) A battery pack in which the conductive metal plate (3) is extended to the side surface of the case (2). 3. A secondary battery (1) is arranged in three rows and housed in a case (2), and a surface of the secondary battery (1) is provided on both side surfaces of the secondary batteries (1) arranged in an intermediate row. The battery pack according to claim 2, further comprising a conductive metal plate (3) formed in a waveform along the shape of (2), wherein the conductive metal plate (3) extends to a side surface of the case (2). 4. The number of rechargeable batteries (1) arranged in the middle row is one more than the number of rechargeable batteries (1) arranged in the outer row, and the number of rechargeable batteries (1) arranged in the middle row is larger. The battery pack according to claim 3, wherein an outer row of the secondary batteries (1) is disposed between the valleys. 5. A plurality of secondary batteries (1), a case (2) accommodating these secondary batteries (1), and a conductive metal plate (2) disposed in the case (2). 3), and the case (2) is
A pair of double-sided plates (2A) arranged on both sides, and a side plate (2B) connecting both sides of the double-sided plate (2A), the double-sided plate (2A) has a flat portion, The side plate (2A) is molded with a metal plate, and the secondary batteries (1) are arranged in multiple rows of three or more rows. Secondary batteries stored in (2) and arranged in the middle row
A battery pack comprising a conductive metal plate (3) disposed along the surface of (1), and the conductive metal plate (3) thermally bonded to a side plate (2B).