JPH0389455A - Manganese dry battery - Google Patents

Abstract

PURPOSE:To prevent the burst of a battery and improve safety by providing a gap at the required section between a zinc tube and a sealing body, and providing a notch at the upper section of a caulking section. CONSTITUTION:A gap 12 is provided between the opening tip section 1b of a zinc tube 1 and the upper face of a sealing body 7, the sealing body 7 is pushed up into contact with the tip section 1b when the internal voltage is increased by charging, and a void is generated on a caulking section 1a. A notch section 1c is provided on the zinc tube 1 above the caulking section 1a, and the gas in a battery is discharged to the outside of the battery through this notch section 1c. The burst of the battery caused by erroneous charging is prevented, and a manganese dry battery with high safety is obtained.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Field of Application] The present invention relates to a manganese dry battery in which a resin exterior material is attached to the outer periphery of a zinc can.

[Conventional technology]

For small manganese dry batteries such as AA, AAA, and AAA batteries, as shown in Figure 7, a sealing body (7) is provided at the opening of the zinc can (1). ), the opening of the zinc can (1) is closed by caulking inward the approximate center of the contact area with the sealing body (7) and compressing the sealing body (7) between it and the carbon rod (6). A battery has been proposed in which the zinc can (1) is sealed and packaged with a resin exterior material 01) made of a heat-shrinkable resin tube or a resin label around the outer periphery of the zinc can (1).

This eliminates the use of metal exterior cans used in D-type batteries, increases the internal volume of the zinc can (1), increases the amount of positive electrode mix, electrolyte, etc., and discharges This is to increase capacity.

In the battery of this structure as well, in order to improve the storage characteristics, consideration is given to increasing the sealing performance inside the battery, resulting in a battery with extremely high sealing performance.

Therefore, when the battery is charged due to misuse, electrolysis of the electrolyte occurs, and gas is generated inside the battery.
Accidents may occur such as batteries bursting under high pressure and damaging equipment that uses them.

To explain this in detail, when using four or more batteries connected in series, if one of the batteries is connected in the opposite direction, the battery connected in the opposite direction will be damaged by the other batteries. It will be charged. Furthermore, depending on the device that uses the battery, the battery may be charged due to a circuit failure or the like.

In these cases, when a manganese dry battery is charged, electrolysis of the electrolyte occurs, hydrogen gas and oxygen gas are generated inside the battery, and the internal pressure of the battery increases, causing the battery to burst under high pressure. Become.

When this battery ruptures, the sealing body (7
), positive electrode mixture (4), etc. may be scattered around, causing not only damage to equipment using batteries, but also danger to the human body.

[The invention tries to solve i! Iu: + As mentioned above, when this type of manganese dry battery is charged due to misuse, gas is generated inside the battery, the internal pressure of the battery increases, and the battery ruptures under high pressure. was there.

Therefore, an object of the present invention is to provide a highly safe manganese dry battery by preventing the battery from bursting due to the above-mentioned misuse.

[Means to solve the problem]

The present invention provides a gap between the opening end of the zinc can and the top surface of the closure, and a cut, hole, or groove for venting gas above the caulking part of the zinc can in contact with the closure. By providing this, the above objective has been achieved.

[Effect]

The operation will be explained with reference to FIGS. 1 to 4 corresponding to the embodiment.

First, when the battery is in normal condition and the internal pressure of the battery has not increased, as shown in Figure 1, a zinc can (1
) The sealing body (7) is strongly compressed at the caulked portion (1a) to maintain high sealing performance.

However, if the internal pressure of the battery increases due to charging, as shown in Figure 2, the sealing body (7)
is pushed up to the point where it comes into contact with the opening tip (1b) of. At this time, the part of the sealing body (7) that was in contact with the caulked part (1a) does not return to its original state (it is pushed upward from the caulked part (1a) while remaining compressed and depressed). Therefore, if a gap a is created between the zinc can (1) and a notch (1c) is provided in the open part on the side of this gap, the gas inside the battery will escape to the outside of the battery through that notch (1C). This reduces the internal pressure of the battery and prevents the battery from exploding.
In place of c), if a hole (1d) as shown in Fig. 5 or a cut groove (le) as shown in Fig. 6 is provided, the gas inside the battery will leak as in the case of the cut (1c). It exits to the outside of the battery through these holes (1d) or kerfs (le), reducing the internal pressure of the battery and preventing the battery from bursting.

〔Example〕

Next, the present invention will be explained in more detail with reference to Examples.

Example 1 In Example 1, an example will be described in which a AAA-sized manganese dry battery is provided with a gas venting cut above the caulked portion of the contact portion with the closure of a zinc can.

First, the overall structure of the battery will be explained based on FIG. 1.

In the figure, (1) is a zinc can, and this zinc can (1) houses a separator (2), a bottom paper (3), a positive electrode mixture (4), an electrolyte, and a top paper (5). There is.

The lower part of the carbon rod (6) penetrates the center part of the top cover paper (5) and reaches the inside of the positive electrode mixture (4), and the upper end part of the carbon rod (6) penetrates the center part of the sealing body (7). It passes through the through hole (7a) and projects upward from the sealing body (7).

A sealing material layer (8) is provided on the top of the top cover paper (5) to improve the sealing properties of the battery.

The sealing body (7) is arranged at the opening of the zinc can (1), and is annularly caulked by caulking inward approximately the center of the contact area of the zinc can (1) with the sealing body (7). A portion (1a) is formed, and by this caulking, the sealing body (7) is attached to the zinc can (1a).
) and the carbon rod (6), the opening of the zinc can (1) is sealed, and the inside of the battery is kept in a sealed state.

The open end (1b) of the zinc can (1) is bent inward prior to the caulking, and the zinc can (1) is bent inward during the caulking.
)'s opening tip (1b>) spreads outward to form the caulked part (1b).
This prevents the tightening force in a) from decreasing.

A gap 021 is provided between the open end (1b) of the bent zinc can (1) and the top surface of the sealing body (7), and when the pressure inside the battery increases, the sealing The part where the body (7) moves upward and becomes depressed due to contact with the caulking part (1a) of the sealing body (7) is at the notch (1c) provided in the zinc can (1). It is possible to move up to.

A positive terminal plate (9) is fitted to the head of the carbon rod (6),
The peripheral edge of the positive terminal plate (9) bites into the sealing body (7), thereby fixing the positive terminal Fi, (9).

A negative electrode terminal plate 0ω is fitted to the bottom of the zinc can (1), and an exterior material 00 is attached to the outer periphery of the zinc can (1), which connects the outer peripheral surface of the zinc can (1) and the negative electrode. Terminal board 00
) is coated on the bottom periphery.

The above-mentioned exterior material 00 is made of a heat-shrinkable resin tube or a resin label. In this example, the surface of the heat-shrinkable resin tube made of vinyl chloride resin is marked with specified information (for example, product name, manufacturer name, handling precautions, etc.). Exterior material 01 is a material on which information such as information is printed and also serves as a label.
) is used as.

A gas venting notch (l) is provided above the caulking part (1a) of the contact part with the sealing body (7) of the zinc can (1).
C) is provided.

The zinc can (1) before being used for battery assembly is as shown in Figure 4, and three notches (1c) are provided at equal intervals in the circumferential direction from the open end of the zinc can (1) downward. It is being Then, a battery is assembled using this zinc can (1), and the zinc can (1) before the exterior material (10) is attached to its outer periphery.
) is as shown in Fig. 3.

The above cut (1c) has a width of 1 mm and is the open end of the zinc can (1) [However, the open end when the open end (1b) is not bent, the same applies below]
It is provided at a depth of 2.5 ++n. Note that the upper end of the caulked part (1a) of the zinc can (+) is located at a distance of 2.7 mm from the open end of the zinc can (1), and due to the pressure increase inside the battery, the sealing body (7) When the sealing member (7) is pushed up and moved upward, the portion of the sealing body (7) that is recessed due to welding with the caulking portion (1a) has its upper end aligned with the above-mentioned notch (
1c) will be located above the lower end.

Example 2 In place of the notch (1c) in the battery of Example 1, a zinc can (1) with a gas vent hole (1d) was used,
Assembled 4 AAA manganese batteries.

That is, the zinc can (1) before being used for battery assembly is as shown in Fig. 5, and four holes (1d) are formed at equal intervals in the circumferential direction near the open end of the zinc can (+). is provided. The diameter of this hole (1d) is 0.8 mm, its lowest end is located 2.5 mm from the open end of the zinc can (1), and the upper end of the caulked part (1a) of the zinc can (1) is It is located 2.7m from the opening end. And this hole (
1d) will be located above the caulking part (1a) when the battery is assembled.

As mentioned above, in the battery of Example 2, above the caulking part (1a) of the zinc can (1) in contact with the sealing body (7),
The structure is the same as in Example 1 except that a gas venting hole (1d) is provided in place of the notch (1c).

Example 3 A AAA-sized manganese dry battery was assembled using a zinc can (1) provided with a gas vent groove (le) in place of the notch (1c) in the battery of Example 1.

That is, the zinc can (+) before being used for battery assembly is as shown in Figure 6, with four grooves spaced at equal intervals in the circumferential direction from the open end of the zinc can (1) downward. (1e)
is provided. Zinc can (1) with this kerf (1e)
The depth from the open end of the zinc can is 2.5 mm.
) The upper end of the caulked part (1a) is 2.7ms+ from the open end.
It is located at. And this kerf (1e)
will be located above the caulked portion (1a) when the battery is assembled.

As mentioned above, in the battery of Example 3, above the caulking part (1a) of the contact part with the sealing body (7) of the zinc can (1),
Grooves for gas release (1e) instead of notches (1c)
The structure is the same as that of the first embodiment except that .

Comparative Example 1 A manganese dry battery having a conventional configuration as shown in FIG. 7 was manufactured.

That is, the battery of Comparative Example 1 has notches (1c), holes (1d), and grooves (1e) above the caulked portion (1a) of the contact portion with the closure (7) of the zinc can (1). However, the configuration other than the above is the same as that of the first embodiment.

20 each of the batteries of Examples 1 to 3 and the battery of Comparative Example 1
Each battery was charged at a constant current of 67 mA to determine the number of batteries that would explode. The results are shown in Table 1 in terms of rupture incidence.

Table 1 As shown in Table 1, the batteries of Examples 1 to 3 of the present invention were:
It has been revealed that there is nothing that can cause an explosion, and even if it is charged due to misuse, it will not explode, making it highly safe.

In addition, in the example, there are 3 incisions (IC) for gas venting.
Four holes (1d) and four kerfs (1e) were provided.
1e) etc. may be one each.

The gas venting notch (1C), hole (1d) or groove (1e) is provided above the caulking part (1a) of the contact part of the closure (7) of the zinc can (1). The position of the lower end is determined from the upper end of the caulked part (1a) to the sealing body (
7) may be set up to a position corresponding to the upper end of the portion where the sealing body (7) was in contact with the caulking portion (1a) when the sealing body (7) was pushed up due to the rise in pressure inside the battery.

In the above example, a heat-shrinkable resin tube was used as the exterior material OD, but instead, a resin label may be used as the exterior material 00. As such a resin label, for example, a resin sheet A sheet with specified information printed on the surface and a pressure-sensitive adhesive coated on the back side, or a thin metal layer such as an aluminum vapor-deposited film on the back side of a resin sheet, and a pressure-sensitive adhesive coated on the thin metal layer. The heat-shrinkable resin tube or resin label used as the exterior material 00 in the present invention is usually called a resin exterior material, but as is clear from the above examples, resin It may be made of resin as the main material, and is not required to be made only of resin.

〔Effect of the invention〕

As explained above, in the present invention, a gas venting notch (1c), a hole (1d) or a notch is provided above the caulking part (1a) of the zinc can (1) in contact with the closure body (7). By providing the groove (1e), it was possible to prevent the battery from exploding even if it was accidentally charged, and to improve the safety of the battery against misuse.

[Brief explanation of drawings]

FIG. 1 is a sectional view showing a battery according to Example 1 of the present invention. FIG. 2 is an enlarged sectional view of a main part of the battery shown in FIG. 1 for explaining a state in which gas inside the battery is released to the outside of the battery when the internal pressure of the battery increases. FIG. 3 is a front view of the main parts of the battery shown in FIG. 1, showing a state before an exterior material is attached to the outer periphery of the zinc can. FIG. 4 is a perspective view of essential parts of the zinc can used in the battery shown in FIG. 1. FIG. 5 is a perspective view of a main part of a zinc can used in a battery according to Example 2 of the present invention. FIG. 6 is a perspective view of a main part of a zinc can used in a battery according to Example 3 of the present invention. FIG. 7 is a sectional view showing a conventional battery.

Claims (1)

[Claims] (1) Zinc can (1), separator (2), bottom paper (3),
Positive electrode mixture (4), electrolyte, top cover paper (5), carbon rod (6)
, a sealing body (7), an exterior material (11) consisting of a heat-shrinkable resin tube or a resin label, the separator (2), the bottom paper (3), the positive electrode mixture (4),
The electrolytic solution and the top paper (5) are housed in the zinc can (1), and the sealing body (7) is placed at the opening of the zinc can (1), and the sealing body (7) is placed in the center of the sealing body (7). The upper end of the carbon rod (6) passes through the through hole (7a), and the opening tip (1b) of the zinc can (1) is bent inward to form the sealing body (1) of the zinc can (1). 7) is caulked inward to form an annular caulking portion (1a
) is formed, and the opening of the zinc can (1) is formed by the above-mentioned sealing body (
7), and an exterior material (11) made of a heat-shrinkable resin tube or a resin label is attached to the outer periphery of the zinc can (1). Opening tip (1b) and sealing body (7)
A gap (12) is provided between the upper surface of the zinc can (1) and a gas venting notch (1c) above the caulked portion (1a) of the contact portion with the closure body (7) of the zinc can (1);
A manganese dry battery characterized by having a hole (1d) or a cut groove (1e).