KR19980053626U - Ni-MH Battery Module Structure - Google Patents

Abstract

The present invention relates to the structure of the Ni-MH battery module, and more particularly, to maximize the charge and discharge efficiency by improving the heat dissipation generated during charging and discharging of the Ni-MH battery, and to improve the performance of the battery. Ni-MH battery module structure for;

One side of one Ni-MH battery 4 and one side of the other Ni-MH battery 4 are in close contact with each other in order, and are arranged along a circumference of the Ni-MH battery module 2. In the Ni-MH battery module (2) connected in series by banding in a band (6) at intervals;

Between the Ni-MH battery 4 and the Ni-MH battery 4 for dissipating heat emitted from the side surfaces of both Ni-MH batteries 4 during charging and discharging of the Ni-MH battery 4. It characterized in that the heat radiation means (8) made.

Description

Ni-MH Battery Module Structure

The present invention relates to the structure of the Ni-MH battery module, and more particularly, to maximize the charge and discharge efficiency by improving the heat dissipation generated during charging and discharging of the Ni-MH battery, and to improve the performance of the battery. It relates to a Ni-MH battery module structure for.

In general, Ni-MH batteries accumulate electrical energy by using nickel as a positive electrode and hydrogen storage alloy (Metal Hydryde) as a negative electrode, and connecting the plurality of Ni-MH batteries (10-11) in series. It is called Ni-MH battery module.

Looking at the structure of such a Ni-MH battery module, conventionally, as shown in Figure 2 Ni-MH battery module 100 is one side of one Ni-MH battery 102 and one side of the other Ni-MH battery 102 The Ni-MH battery modules 100 are in a state in which they are in close contact with each other in order, and are bundled in a band 104 at predetermined intervals along a circumference and connected in series to have a quadrangular shape.

Accordingly, when the internal temperature of the Ni-MH battery 102 rises during charging and discharging of the Ni-MH battery module 100, the Ni-MH battery module 100 is positioned at both ends thereof. By cooling the heat through the side of each of the Ni-MH battery module 100 is to be cooled.

However, since the conventional Ni-MH battery module is made by simply connecting the Ni-MH battery and the Ni-MH battery in close contact, the Ni-MH battery module does not effectively dissipate heat generated during charging and discharging of the Ni-MH battery. There existed a non-limiting point which falls and the performance of a Ni-MH battery module falls.

Therefore, the present invention was devised to solve the above problems, and the object of the present invention is to effectively dissipate heat generated during charging and discharging of a Ni-MH battery, thereby maximizing charge and discharge efficiency and performance of the battery. To provide a Ni-MH battery module structure to improve the.

In order to achieve the above object, the present invention, in the state in which one side of one Ni-MH battery and one side of the other Ni-MH battery in order to closely adhere to each other in order, the circumference of the Ni-MH battery module In the Ni-MH battery module to be connected in series by banding at a predetermined interval according to;

Between the Ni-MH battery and the Ni-MH battery is characterized in that the heat dissipation means for dissipating heat emitted from the side of both Ni-MH battery during charging and discharging of the Ni-MH battery.

Accordingly, when the internal temperature of the Ni-MH battery rises during charging and discharging of the Ni-MH battery, the Ni-MH battery emits heat to the outside thereof, and the heat emitted through the side of the Ni-MH battery is dissipated. Delivered by means.

The heat transferred to the heat dissipation means lowers the internal temperature of the Ni-MH battery while dissipating to the outside of the Ni-MH battery module.

1 is a perspective view showing the structure of a Ni-MH battery module according to the present invention.

Figure 2 is a perspective view showing the structure of a conventional Ni-MH battery module.

* Description of the symbols for the main parts of the drawings *

2: Ni-MH battery module 4: Ni-MH battery

6: band 8: heat dissipation means

Hereinafter, a preferred embodiment of the present invention with reference to the accompanying drawings in detail as follows.

1 is a perspective view showing the structure of a Ni-MH battery module according to the present invention.

The Ni-MH battery module 2 has the Ni-MH battery in a state in which one side of one Ni-MH battery 4 and one side of the other Ni-MH battery 4 are in close contact with each other in order. Along the circumference of the module 2 is bundled with a band 6 at a predetermined interval and connected in series to have a rectangular shape.

The amount of charge and discharge of the Ni-MH battery 4 in order to improve the performance of the Ni-MH battery module 2 between the Ni-MH battery 4 and the Ni-MH battery 4. The heat radiating means 8 for radiating heat radiated from the side surface of the Ni-MH battery 4 is combined.

The heat dissipation means 8 includes a heat dissipation plate 10 having a predetermined size formed of an extruded aluminum sheet to dissipate heat emitted from the side surface of the Ni-MH battery 4; It is formed on the heat sink 10 with a predetermined interval comprises a plurality of air holes 12 that can easily dissipate heat transferred to the heat sink 10.

The heat sink 10 is preferably made of the same size as the side of the Ni-MH battery (4) in order to be able to effectively dissipate heat generated from the Ni-MH battery (4).

In addition, the air hole 12 is preferably disposed at a predetermined interval on the heat sink 10 to more effectively radiate the heat transferred to the heat sink (10).

Accordingly, when the Ni-MH battery 4 is charged and discharged, the internal temperature of the Ni-MH battery 4 increases, and the Ni-MH battery 4 emits heat to the outside thereof. The Ni-MH battery Heat released through the side of the (4) is transmitted to the heat sink 10 of the heat dissipation means (8).

The heat transferred to the heat sink 10 lowers the internal temperature of the Ni-MH battery 4 while being radiated to the outside of the Ni-MH battery module 2 as well as being radiated through the air hole 10.

As such, the present invention can effectively dissipate heat generated during charging and discharging of the Ni-MH battery, thereby maximizing charging and discharging efficiency and improving battery performance.

Claims (4)

One side of one Ni-MH battery 4 and one side of the other Ni-MH battery 4 are in close contact with each other in order, and are arranged along a circumference of the Ni-MH battery module 2. In the Ni-MH battery module (2) connected in series by banding in a band (6) at intervals; Between the Ni-MH battery 4 and the Ni-MH battery 4 for dissipating heat emitted from the side surfaces of both Ni-MH batteries 4 during charging and discharging of the Ni-MH battery 4. Ni-MH battery module structure characterized in that the heat dissipation means (8). The heat dissipation means (8) according to claim 1, further comprising: a heat dissipation plate (10) for dissipating heat emitted from the side of the Ni-MH battery (4); Ni-MH battery module structure characterized in that it comprises a plurality of air holes (12) formed on the heat sink 10 at predetermined intervals to easily dissipate heat transferred to the heat sink (10). The Ni-MH battery (4) according to claim 2, characterized in that the heat sink (10) is made of the same size as the side of the Ni-MH battery (4) in order to effectively dissipate heat generated from the Ni-MH battery (4). -MH battery module structure. The Ni-MH battery module structure according to claim 2, wherein the air holes (12) are arranged at regular intervals on the heat sink (10) to more effectively radiate heat transferred to the heat sink (10).