JPH02106869A - Pack structure of lead-acid battery - Google Patents

Abstract

PURPOSE:To improve the capacity efficiency by engagingly locking two metal plate in such a manner as to pull against each other by protruded parts, and forming the protruded parts not so to project outward over the bent part side face. CONSTITUTION:Metal plates 11, 12 are also reinforcing plates to add a group pressure to each laminated element of a crude battery 5. Plane parts 13, 14 have a U shape by bending their both sides inward, respectively, bent parts 15, 16 have protruded parts 19, 20 on their end side parts 17, 18, and the protruded parts 19, 20 are formed of a pair of engaging part 21 and locking part 22. The protruded parts 19, 20 form four pairs in total, with two pairs to every one side of each bent part 15, 16 of the metal plates 11, 12, to engagingly lock the metal plates 11, 12 mutually. Hence, the capacity efficiency can be improved.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to the pack structure of lead-acid batteries, particularly small sealed lead-acid batteries.

PRIOR TECHNOLOGY There are many structures in which two metal plates are mutually locked, but the most common ones are shown in Figures 8a, b, and c.
, d. The pair of locking portions that lock each other are made of overlapping metal pieces that are locked together. The number of overlapping plates of these body stops is usually 3 or more.
Many have 4 pieces. In terms of strength, there are very few cases where only two pieces are attached to each other, and only those using spot welding or adhesives are rarely seen.

PROBLEM TO BE SOLVED BY THE INVENTION As mentioned above, the present invention reduces the overlapping υ of the metal plates of the locking portion and reduces the external dimensions to the extent possible to improve the volumetric efficiency and The purpose is to improve the volumetric efficiency (ratio of battery capacity per body volume of small sealed lead acid batteries).

Means for Solving All the Problems The present invention suppresses the overlap of metal plates provided with a pair of locking portions that lock each other as described in 111 to no more than two sheets, and allows the metal plates to overlap one another by the wheel shape of the metal plate. The bent part should be placed on the inner wall side of the bent part bent into a U-shape, and in relation to the internal structure of the unit cell placed inside the metal plate, the end of one plate of the element By positioning a protruding portion by overlapping the metal plates No. 111 in the section, and integrating these structures No. 111, the volumetric efficiency is improved.

For production ,+The external dimensions of the battery are the anode plate that makes up the battery.

It is determined by the cathode plate and the separator, but since the separator is usually set to be thicker than the electrode plate, the external dimensions of the unit cell depend on the separator. The separator (is made of ultra-fine glass fiber and is impregnated with an electrolyte, so it easily undergoes dimensional changes when external force is applied from protrusions etc. However, the overall l' 71..4+1:i small If restrictions are imposed on the external dimensions, the internal volume will naturally become smaller, and the electrolyte impregnated in the separator will be squeezed out and leak from the exhaust valve.

If only the locking portion protrudes inward, the reduction in volume is extremely small and its proportion to the total volume is small. In addition, if the position of the protrusion and the positional relationship between the battery's electrode plate and the separator are appropriately selected, it is possible to prevent the metal plates from interlocking with each other without depleting the separator, that is, without changing the volume of the battery. 14 can be provided to protrude toward the inner wall side of the metal plate.

EXAMPLE An example of the present invention will be described. To explain the structure of the unswitchable unit cell, in the figure, 1 is a positive plate, 2 is a negative plate, and 3 is a separator sandwiched between the two electrode plates. The elements of the anode plate 1, the cathode plate 2, and the separator 3 are laminated and covered with a bag-like thin film 9, and each of these elements is impregnated with the electrolyte 4 to form the unit cell 5 shown in FIGS. 3 and 4. do. This unit cell 6 is provided with an anode column 6, a cathode column 7, and a safety valve 8, which are manufactured from the inside of the unit cell 5 to the outside as shown in the figure. 7 and 6 are connected to the anode plate 1, and the cathode pillars 7 are also connected to the cathode plate 7 and serve as electrical output terminals of the unit cell.

The safety valve 8 is for discharging gas generated within the unit cell 5. For the bag-shaped thin film 9, importance is placed on the airtightness of the anode column, cathode column, and safety valve 8 portions that seal the primary pond 5 from the outside air. The unit cells 5 are stacked to form an assembled battery 10, with their adjoining surfaces being adhesively fixed to each other via adhesive or double-sided tape (not shown). Reference numerals 11 and 12 are two metal plates that abut the entire surface of the assembled battery 10 from both sides. The metal plates 11 and 12 are also reinforcing plates for applying group pressure to each stacked element of the unit cell 5.
1.12 is formed by bending both sides of the plane portion 13.14 inward to form a U-shape, and the end portion 17.18 of the bent portion 16.16 has a protruding portion 19.20. and the protrusion 1
9.20 consists of a pair of fitting parts 21 and locking parts 22.

The fitting part 21 has a hole 2 into which the tip of the locking part 22 is pushed and secured.
3, and a stepped portion 24 in which the plate thickness is depressed one step inward. Similarly, the locking portion 22 is located one step inward by the thickness of the metal plate 11 from the surface of the bent 6” portion 15.

Such protrusions are formed in each curved portion 16. of the metal plate 11.12.
These metal plates 11 and 12'i form a total of four pairs, two on each side of the metal plates 11 and 16, and are interlocked with each other. FIG. 4 shows the state of locking in detail, where the plate thicknesses fall inward and lock each other at the stepped portions.

The protrusions 19 and 20 provided at the end sides of the bent portions 16 and 16 are tapered outwardly at an angle a (approximately 6 to 16 degrees) with respect to the side surfaces of the bent portions.

This is to make it easier to set up the assembled battery 10 when inserting it into the metal plates 11 and 12. In the mutually locked state, the metal plates 11 and 12 are stretched almost straight due to the attraction between them due to the group pressure, so that they do not bulge out from the sides. In other words, it is α-〇0. The battery pack unit 26 assembled in this manner is covered with battery tape 26 and a battery tape 26 as shown in FIG. 7, thereby completely eliminating battery puncture.

This battery puncture has battery terminal portions 28 and 29, which serve as power terminals for a small sealed lead storage battery.

7. Lead wires (not shown) are connected to these battery terminals 28 and 29 in series with the G pole pole of the internal unit cell 5.
are wired respectively.

Effects of the Invention As described above, between the assembled battery unit 26 which is sandwiched and reinforced between the two metal plates 11.12 and the battery case, there is a pair of mutual engagement portions of the metal plates 11.12 on both sides. Although it has one protruding part, there is no protruding part ρ5, and the structure is such that only one metal plate is present on the side of the unit cell 6 and the inner surface of the battery case 26, 27. It constitutes a battery pack with high volumetric efficiency.

tGilAlthough the four steps and locking parts of the fitting part mentioned above are provided in total, it is one of the parts of the unit battery in that they protrude inward by the thickness of the plate.
However, this reduction in volume is extremely small as a whole, and if the stepped portion and the locking portion are aligned with the position of the electrode plate of the unit cell, the cavity of the original Kameike will be reduced. (Fig. 4), and the battery characteristics are hardly affected.

[Brief explanation of the drawing]

Fig. 1 is a structural diagram of a metal plate constituting the assembled battery unit of the present invention, Fig. 2 is a detailed view showing a pair of protrusions A, Fig. 3 is a cross-sectional view of unit cells and stacked unit cells, and Fig. 4 Fig. 3 is a detailed view of the opening, Fig. 5 is a detailed view showing a cross section of the protrusion of the metal plate, Fig. 6 is a perspective view of the m battery unit, Fig. 7 is a perspective view of a punctured battery, and Fig. 8 is a detailed view of the metal plate. It is a sectional view showing a locking structure of a plate. 1... Anode plate, 2... Cathode plate, 3...
... Separator, 4 ... Electrolyte, 6 ...
...Battery, 9...Bag-shaped thin film, 1o...
Assembled battery, 11.12...Metal plate, 16.16.
...Bending part, 17.18... End part, 1
9.20... Protrusion part, 21... Fitting part, 22... Locking part, 24... Step part. Name of agent: Patent attorney Shigetaka Awano et al.

Claims (2)

[Claims] (1) A plurality of unit cells are stacked each consisting of an anode plate, a cathode plate, a separator interposed between these plates, and an electrolytic solution impregnated and held in the bipolar plates and the separator and covered with a bag-like thin film. An assembled battery and two metal plates that abut the entire surface from both sides of the assembled battery are arranged, and the metal plates have both sides bent inward to form a U-shape, and have this bent part. Two metal plates are made to face each other, and a protrusion consisting of a pair of fitting parts and a locking part is provided on the edge of the bent part, and the two metal plates are engaged so as to be drawn together by this protrusion. 1. A pack structure for a lead-acid battery, characterized in that the projecting portion is configured such that the projecting portion does not protrude outward from the side surface of the bent portion. (2) The engaging step portion and the locking portion of the protruding portion having the fitting portion and the locking portion are located correspondingly to the electrode plate portion of the unit cell. Pack structure of lead acid battery.