KR19980044142U - Ni-MH Battery Module Structure - Google Patents

Abstract

The present invention relates to a structure of a Ni-MH battery module, and more particularly, to maximize heat dissipation efficiency by efficiently dissipating heat generated from a Ni-MH battery, and a Ni-MH battery module for improving battery performance. The structure relates to a Ni-MH battery module (2) having a rectangular shape by connecting a plurality of Ni-MH batteries (4) at regular intervals, the front and rear surfaces of the Ni-MH battery module (2) The cross section is characterized in that the heat dissipation means 6 for dissipating heat generated from the Ni-MH battery 4 are combined by a predetermined coupling means.

Description

Ni-MH Battery Module Structure

The present invention relates to a structure of a Ni-MH battery module, and more particularly, to maximize heat dissipation efficiency by effectively dissipating heat generated from a Ni-MH battery, and a Ni-MH battery module for improving battery performance. It's about structure.

In general, a Ni-MH battery is one in which nickel is used as a positive electrode and a hydrogen storage alloy (Metal Hydryde) is used as a negative electrode to store electrical energy. The Ni-MH battery is formed by connecting a plurality of Ni-MH batteries (10-11). -MH battery module.

Looking at the structure of such a Ni-MH battery module, as shown in FIG. 2, a heat sink having the same size on both sides of the Ni-MH battery module 104 made of a plurality of Ni-MH batteries 102 and formed of an aluminum extrusion material ( 106).

The heat dissipation plate 106 was banded and fixed along the periphery of the Ni-MH battery module 104 at predetermined intervals.

Accordingly, when the internal temperature of the Ni-MH battery 102 rises when the Ni-MH battery module 104 is fully charged, heat is transferred to the heat sink 106, and the heat transferred to the heat sink 106 is Ni. It is released to both sides of the -MH battery module 104 is to cool the heat of the Ni-MH battery (102).

However, in the related art, heat sinks are installed at both ends of the Ni-MH battery module, and the heat sink is fixed to the Ni-MH battery module by using a plurality of bands, thereby preventing the heat radiation of the Ni-MH battery effectively. Thereby, there was a problem that the charging efficiency was lowered and the performance of the Ni-MH battery was lowered.

Therefore, the present invention has been devised to solve the above problems, and the object of the present invention is to effectively dissipate heat generated from Ni-MH batteries, thereby maximizing charging efficiency and improving the performance of the batteries. An MH battery module structure is provided.

In order to achieve the above object, the present invention, in the Ni-MH battery module made of a rectangular shape by connecting a plurality of Ni-MH batteries at regular intervals, each of the front and rear end surfaces of the Ni-MH battery module Heat dissipation means for dissipating heat generated from the Ni-MH battery is characterized in that the combination is made by a predetermined coupling means.

Accordingly, when the internal temperature of the Ni-MH battery rises when the Ni-MH battery module is fully charged, heat generated from the Ni-MH battery is transferred to the heat radiating means.

The heat transferred to the heat dissipation means lowers the internal temperature of the Ni-MH battery while dissipating to the front and rear 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: 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 is formed in a rectangular shape by connecting a plurality of Ni-MH batteries 4 at regular intervals.

The heat dissipation means 6 for dissipating heat generated from the Ni-MH battery 4 is coupled to a front end face and a rear end face of the Ni-MH battery module 2 by predetermined coupling means.

The heat dissipation means 6 includes a heat dissipation plate 8 having a predetermined size formed of an extruded aluminum sheet to dissipate heat generated from the Ni-MH battery 4; The heat sink 8 comprises several air holes 10 capable of dissipating heat that is radiated therefrom in the longitudinal direction again.

The heat sink 8 is preferably made of the same size as the front and rear surfaces of the Ni-MH battery module 2 to effectively dissipate heat generated from the Ni-MH battery (4).

In addition, the air hole 10 is made of a predetermined size to more effectively dissipate heat radiated from the heat sink 8 again, it is preferably disposed at regular intervals along the Ni-MH battery module (2).

The coupling means arranges the band 12 on both sides of the Ni-MH battery module 2 at predetermined intervals, and couples the band 12 and the heat sink 8 by the bolts 14.

Accordingly, when the internal temperature of the Ni-MH battery 4 rises when the Ni-MH battery module 2 is fully charged, the heat generated from the Ni-MH battery 4 is dissipated by the heat sink 8 of the heat dissipation means 6. Is passed to.

The heat transferred to the heat sink 8 is radiated to the front and rear of the Ni-MH battery module 2, and the heat can be radiated to the outside again along the longitudinal direction of the heat sink 8 through the air hole 10. will be.

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

Claims (5)

In the Ni-MH battery module 2 made of a rectangular shape by connecting a plurality of Ni-MH batteries 4 at regular intervals, The heat dissipation means 6 for dissipating heat generated from the Ni-MH battery 4 is coupled to a front end face and a rear end face of the Ni-MH battery module 2 by a predetermined coupling means. Ni-MH battery module structure. The heat dissipation means (6) according to claim 1, further comprising: a heat dissipation plate (8) of a predetermined size for dissipating heat generated from the Ni-MH battery (4); Ni-MH battery module structure characterized in that the heat sink comprises a plurality of air holes (10) which can radiate heat again radiating heat therefrom in the longitudinal direction. The Ni-MH battery module structure according to claim 2, wherein the heat sink (8) has the same size as the front and rear surfaces of the Ni-MH battery module (2). The Ni-MH battery module structure according to claim 2, wherein the air holes (10) are arranged at regular intervals along the Ni-MH battery module (2). The method of claim 1, wherein the coupling means is arranged on both sides of the Ni-MH battery module (2) with a band 12 at a predetermined interval, the band 12 and the heat sink (8) by a bolt (14) Ni-MH battery module structure, characterized in that made by.