JPH07134976A - Cell of rustproof structure - Google Patents

Abstract

PURPOSE:To efficiently air-cool a cell without obstructing the action of a safety valve. CONSTITUTION:A thermally contractive tube 2 covers the outer circumferential side face 1A of a unit cell 1 and the circumference part, of an electrode end face 1B on a safety valve side of the unit cell 1. In the safety valve side electrode end face 1B, watertight structure adhesion is accomplished between a seal plate 4 provided with an electrode through hole and the thermally contractive tube 2 in the circumference part via a force peeling adhesive layer 3. Through the electrode through hole in the seal plate 4, a lead tab 5 is connected to an electrode on the safety valve side. An adhesive 6 is watertightly applied into a clearance between the electrode though hole and the lead tab 5. In this way, coating is carried out and a waterproof condition is accomplished under such a condition as pressurized gas inside the cell is discharged, when the safety valve is opened. Therefore, the unit cell 1 can be efficiently air-cooled without obstructing the action of the safety valve in the case of heavy-current.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a battery having a rust preventive structure which is mainly incorporated in an electric vehicle or a device used in a place where water tends to get wet.

[0002]

2. Description of the Related Art As a unit cell, a metal case having an iron surface plated with nickel is used. When water adheres to the surface of the metal case, nickel is peeled off to expose the iron and rust. Rust on the battery causes poor contact, increases contact resistance, and hinders the normal valve differential of the safety valve. In order to prevent this adverse effect, as a battery used outdoors, a plurality of unit cells are housed in a case and the case is hermetically sealed.

[0003]

The battery of this structure has a feature that it can be used outdoors with peace of mind because the case can protect the unit cell in a watertight manner. However, this structure can be adopted only for a small capacity. This is because the unit cell cannot be effectively cooled by air when used for the purpose of extracting a large current.
A battery used as a power source of an electric vehicle or the like has a large discharge current and generates a considerable amount of heat, so it is extremely important to efficiently dissipate heat. When the battery heats up and reaches a high temperature, the heat significantly deteriorates the battery performance. Batteries for large currents used in applications such as electric vehicles have a large capacity, and in order to shorten the charging time, it is important that the charging current is considerably large and the heat generated during charging is effectively cooled by air. . Therefore, even if the battery used with a large current is used outdoors, it is not possible to waterproof the case accommodating a plurality of unit cells as a sealed structure. Therefore, the conventional battery for large current has a drawback that it is difficult to effectively cool the battery as a waterproof structure.

The battery is equipped with a safety valve that prevents the outer can from bursting. The safety valve opens when the internal pressure of the battery rises abnormally. The opened safety valve exhausts the gas inside the battery to prevent the outer can from bursting. The provision of the safety valve makes the sealed watertight structure of the battery difficult. If the safety valve is opened when the safety valve is opened,
This is because the gas in the battery cannot be discharged quickly.

The present invention was developed for the purpose of solving these drawbacks. The important object of the present invention is to
An object of the present invention is to provide a rust-proof structure battery capable of having a waterproof structure in a state where the unit cell can be efficiently air-cooled without inhibiting the operation of the safety valve.

[0006]

The battery of the rust preventive structure of the present invention has the following constitution in order to achieve the above-mentioned object. (A) In order to cover the outer peripheral side surface 1A of the unit cell 1, the unit cell 1 is covered with a heat-shrinkable tube 2. (B) The heat shrinkable tube 2 covering the outer peripheral side surface 1A is
The peripheral portion of the electrode end surface 1B on the safety valve side of the battery is covered. The heat-shrinkable tube 2 is cut longer than the entire length of the unit cell 1 and protrudes from the electrode end surface 1B, and the protruding portion is contracted to cover the outer periphery of the electrode end surface 1B in a ring shape. (C) The heat-shrinkable tube 2 at the peripheral portion of the safety valve side electrode end face 1B has the seal plate 4 bonded in a watertight manner via the pressure release adhesive layer 3. The seal plate 4 opens the electrode through hole 4A. The pressure release adhesive layer 3 is released when the safety valve of the unit cell 1 is opened and a gas pressure is applied to the seal plate 4. When the pressure release adhesive layer 3 is peeled off, a gap is formed between the seal plate 4 and the heat shrinkable tube 2, and the gas is exhausted. (D) The lead tab 5 is inserted into the electrode through hole 4A of the seal plate 4, and the end portion of the lead tab 5 is connected to the electrode on the safety valve side. (E) The adhesive 6 is watertightly applied to the gap between the electrode through hole 4A and the lead tab 5 so that water does not enter. (F) Electrode end surface 1B opposite to the safety valve side electrode end surface 1B
Is covered with a watertight structure so that water does not enter this part. Since a safety valve is not provided on the electrode end surface 1B, an adhesive can be applied between the heat shrinkable tube 2 and the lead tab 5 to cover it in a watertight manner. Further, like the safety valve side electrode end surface 1B, the seal plate 4 may be adhered and an adhesive may be applied between the seal plate 4 and the lead tab 5 to cover it. However, the electrode end face without the safety valve can be bonded to the heat shrinkable tube with the pressure-peelable adhesive layer or an adhesive that does not peel off even when pressure is applied.

Further, the battery of the present invention preferably has the following structure. In the battery, the lead tab 5 is covered with the covering tube 11. The cover tube 11 is the lead tab 5
Not covered. The ends of the lead tabs 5 project from the covering tube 11. An end portion of the lead tab 5 protruding from the covering tube 11 has an adhesive press-fitting hole 12 opened. The adhesive press-fitting hole 12 is located near the welded portion of the lead tab 5 to be welded to the electrode. In the lead tab 5 having the adhesive press-fitting hole 12, the adhesive can be injected into the adhesive press-fitting hole 12 and the back surface of the lead tab 5 can be filled with the adhesive. The adhesive 6 applied to the ends of the lead tabs 5 is used as the covering tube 1
The surface of the lead tab 5 protruding from 1 is covered in a watertight manner.

Further, in the battery of the present invention, a clad material can be used for the lead tab 5. For the clad material,
It is possible to use a laminate of copper and a low conductivity metal layer having lower electrical conductivity than copper, for example, nickel. Furthermore, in the battery of the present invention, the end portion of the lead tab 5 is bent to form the welded portion 5B, and the bend angle (α) of the welded portion 5B is set to an obtuse angle to prevent damage to the lead tab bent portion due to vibration. There is.

[0009]

In the battery of the rustproof structure of the present invention, the outer peripheral side surface 1A of the unit cell 1 and the safety valve side electrode end surface 1B are connected to each other by the heat shrinkable tube 2.
It is watertightly covered with the seal plate 4 and the adhesive 6. For this reason, the unit cell 1 can be made into a watertight structure so that it can be effectively cooled by air. Further, since the seal plate 4 covering the safety valve side electrode end surface 1B is adhered to the heat-shrinkable tube 2 via the pressure release adhesive layer 3, the safety valve opens and the seal plate 4
When a gas pressure is applied to the seal plate 4, the seal plate 4 separates from the heat-shrinkable tube 2 and the gas passing through the safety valve is exhausted to the outside.

[0010]

Embodiments of the present invention will be described below with reference to the drawings. However, the examples described below exemplify a battery for embodying the technical idea of the present invention, and the present invention relates to the materials, shapes, structures, and arrangements of the components constituting the battery as follows. Not specific to.

Further, in this specification, for easy understanding of the claims, the numbers corresponding to the members shown in the embodiments are referred to as "claims column", "action column", and "action column". It is added to the members shown in the section of "Means for Solving the Problems". However, the members shown in the claims are
It is by no means specific to the members of the examples.

In the battery having the rustproof structure shown in the sectional view of FIG. 1, the perspective view of FIG. 2 and the exploded perspective view of FIG. 3, a heat shrinkable tube 2 is attached to an outer peripheral side surface 1A of a unit cell 1. . The unit cell 1 shown in these figures has a cylindrical shape. However, the present invention does not specify the unit cell 1 as a cylindrical shape. For example, the unit cell 1 may be a quadrangular prism or an elliptic cylinder. The unit cell 1 contains a safety valve 7 as shown in FIG.
The safety valve 7 opens when the gas pressure in the battery rises abnormally. The unit cell 1 shown in this figure has a safety valve 7 built in on the + side.

The heat-shrinkable tube 2 covering the outer peripheral side surface 1A of the unit cell 1 is a synthetic resin film which shrinks when heated. The heat-shrinkable tube 2 has a tubular shape thicker than that of the unit cell 1 when the heat-shrinkable tube 2 is not shrunk. The unit cell 1 is inserted into the cylindrical heat-shrinkable tube 2, the heat-shrinkable tube 2 is heat-shrinked, and this is brought into close contact with the outer peripheral side surface 1A of the unit cell 1. As shown in FIGS. 1 and 3, the heat-shrinkable tube 2 covers not only the outer peripheral side surface 1A of the unit cell 1 but also the peripheral edge portion of the electrode end surface 1B. The width (W) with which the heat-shrinkable tube 2 covers the peripheral edge portion of the electrode end surface 1B is, for example, 2 mm to 20 mm, preferably 3 mm to, in order to adhere the seal plate 4 thereto.
It is set in the range of 10 mm. The width (W) with which the heat-shrinkable tube 2 covers the peripheral portion of the electrode end surface 1B can be adjusted by the total length of the heat-shrinkable tube 2. When the total length of the heat-shrinkable tube 2 is made longer than that of the unit cell 1, the width (W) covering the electrode end surface 1B becomes wider. The heat-shrinkable tube 2 shrinks when heated, so as shown in FIG.
It adheres to the peripheral portion of B. The heat-shrinkable tube 2 is in close contact with the surface of the unit cell 1 in a state of being bent 90 degrees at the angle between the outer peripheral side surface 1A of the unit cell 1 and the electrode end surface 1B.

In the battery, a seal plate 4 is adhered to the peripheral portion of the electrode end surface 1B. The seal plate 4 has an insulating property,
It is also a plate material such as plastic that does not allow water to pass through. The seal plate 4 is formed in a shape substantially equal to the outer shape of the electrode end surface 1B so that the electrode end surface 1B of the unit cell 1 can be closed. An electrode through hole 4A for passing the lead tab 5 is provided in the central portion of the seal plate 4. A ring 8 is watertightly bonded to the electrode through hole 4A. The ring 8 prevents the adhesive 6 applied to the gap between the lead tab 5 and the electrode through hole 4A from leaking. The seal plate 4 with the ring 8 is
The lead tab 5 and the seal plate 4 can be reliably made watertight with a small amount of the adhesive 6. The electrode end surface 1B can be finished neatly. The seal plate 4 has the pressure release adhesive layer 3 interposed therebetween.
It is adhered to the surface of the heat-shrinkable tube 2 that covers the peripheral portion of the electrode end surface 1B.

The pressure peeling adhesive layer 3 peels at least a part of the seal plate 4 from the heat shrinkable tube 2 when the safety valve of the unit cell 1 is opened. The safety valve built into the nickel-cadmium battery is designed to open when the internal pressure rises to about 20 kg / cm ² . Therefore, the pressure peeling adhesive layer 3 is designed to have a strength of peeling when the seal plate 4 is pressed by the gas pressure discharged to the outside of the outer can by opening the safety valve. For example, the pressure release adhesive layer 3 can be a double-sided adhesive tape whose both surfaces are coated with an adhesive adhesive.
Double-sided adhesive tape can be used to easily attach the sealing plate to the heat shrink tube. Instead of the double-sided adhesive tape, a tacky adhesive can be used for the pressure release adhesive layer. The sticky adhesive is applied to either or both of the bonding surfaces of the heat-shrinkable tube and the seal plate to bond the seal plate with the heat-shrinkable tube. Further, as the pressure peeling adhesive layer, any adhesive that peels the seal plate from the heat shrink tube when the safety valve opens and gas pressure is applied can be used instead of the adhesive adhesive.

The pressure release adhesive layer 3 removes the seal plate 4 from the heat shrinkable tube 2 when the safety valve is opened. Therefore, the seal plate 4 of the safety valve side electrode end surface 1B needs to be bonded to the heat shrinkable tube 2 via the pressure release adhesive layer 3. This is because the gas inside the electrode passes through the safety valve and is exhausted from between the seal plate 4 and the heat-shrinkable tube 2.

The battery has a heat-shrinkable tube 2 on the electrode end face 1B.
After adhering the seal plate 4 to, the lead tab 5 is spot-welded and connected to the electrode of the unit cell 1. The end portion of the lead tab 5 passes through the electrode end surface 1B of the seal plate 4 and is connected to the electrode of the unit cell 1. The lead tab 5 is a metal plate and the seal plate 4
It is bent as shown in FIG. 3 so as to easily pass through the ring 8.

After the lead tab 5 is connected to the electrode, an adhesive 6 is applied between the lead tab 5 and the electrode through hole 4A. The adhesive 6 is applied inside the ring 8 to seal the gap between the lead tab 5 and the electrode through hole 4A in a watertight manner. The adhesive 6 includes, for example, an epoxy adhesive, a urethane adhesive,
Phenolic adhesives, acrylic adhesives, etc. can be used.

In the battery having the rust preventive structure shown in FIG. 1, the electrodes on both sides of + and − are watertightly closed with the same structure. The electrode end surface 1B on the safety valve side needs to adhere the seal plate 4 to the heat-shrinkable tube 2 via the pressure release adhesive layer 3. This is because gas in the battery is exhausted from between the seal plate 4 and the heat shrink tube 2 when the safety valve is opened. However, the electrode end surface 1B on the side where the safety valve is not incorporated (the negative side of a normal electrode) can have a completely sealed structure. In other words, the function of exhausting the pressurized gas in the electrode is not required. Therefore, the seal plate 4 on this surface does not necessarily have to be adhered to the heat-shrinkable tube 2 via the pressure release adhesive layer 3. The electrode end surface 1B without a safety valve can be adhered to the heat shrinkable tube 2 with the seal plate 4 via a tough adhesive layer that cannot be separated by the pressurized gas pressure in the electrode. Further, the electrode end surface without the safety valve is not shown in the drawing, but without using a sealing plate, the width of the heat shrink tube covering the electrode end surface is widened, and an adhesive is applied between the lead tab and the heat shrink tube. It can also be watertightly coated.

A large-capacity battery covered in a watertight manner with such a structure is rarely used alone. In many cases,
Adjust the output voltage by connecting multiple units in series, or
Used as a battery pack connected in parallel to increase the capacity. In this way, by connecting a plurality of batteries, a battery pack having an optimum capacity and voltage as a power source for an electric vehicle or the like can be obtained.

In this case, it is important to connect a plurality of batteries so that they can be effectively cooled. In particular, a battery pack in which a large number of large-capacity batteries are connected has a large total amount of heat generation,
It is extremely important to effectively cool the battery so that the temperature rise of the battery is as low as possible. Furthermore, it is important to make a battery pack using a large battery compact so that it can be stored in a limited space. Compactness and effective heat dissipation are contradictory properties, and it is quite difficult to satisfy both at the same time. When assembled compactly, it becomes difficult to radiate heat and the battery temperature rises.

FIG. 5 and FIG. 6 show a battery pack improved so as to be compact as a whole and to effectively dissipate heat. In this battery pack, a plurality of batteries are connected using a honeycomb core 9 so that an air cooling duct 10 is formed between the respective batteries. Both ends of the honeycomb core 9 are opened so that air can freely pass through the air-cooling duct 10 of the battery pack. This battery pack is
A battery having an anticorrosive structure is inserted into the hexagonal column of the honeycomb core 9, and the air cooling duct 10 is provided between the adjacent batteries.

For the honeycomb core 9, a flexible and deformable sheet material is used. The honeycomb core 9 is manufactured to be a little small so that the honeycomb core 9 is slightly expanded when the battery is inserted. When the batteries are inserted into the hexagonal columns of the honeycomb core 9, air cooling ducts 10 having the same shape are formed between the batteries as shown in FIG.

The air-cooling duct 10 penetrates the battery pack above and below and allows air to freely pass therethrough. Therefore, the cooling air easily flows through the air cooling duct 10,
The surface of each battery can be cooled uniformly and effectively with cooling air. In particular, inside the air cooling duct 10, the honeycomb core 9 is not brought into close contact with the surface of the battery, and the surface of the battery is forcibly and uniformly cooled by the air flowing through the air cooling duct 10. It is because the honeycomb core 9 does not cover the surface of the battery with the air cooling duct 10.
This is because the surface of the battery located at is directly contacted with air and cooled without passing through the honeycomb core 9.
The air cooling duct 10 can be inside the battery pack. It is difficult to dissipate heat inside the battery pack, and the temperature is especially likely to rise. The battery pack using the honeycomb core 9 is
An air cooling duct 10 having the same shape is formed between the batteries. The surface of the battery, except the part that contacts the adjacent battery,
A considerably large area is located in the air cooling duct 10. Therefore, the battery pack connected by the honeycomb core has a feature that a large number of batteries can be cooled very effectively by flowing cooling air through the air cooling duct 10. In addition, since the batteries can be neatly arranged in a fixed position through the honeycomb core 9, there is also a feature that the outer shape can be made compact.

The lead tab for connecting the positive and negative electrodes of the unit cell may have the shape shown in FIG. The lead tab 5 shown in this figure has two ends branched into two. The branch portion 5A is provided with a welded portion 5B by bending the end portion of the lead tab 5 as shown in the side view of FIG. 8 so that it can be inserted into the electrode through hole 4A of the seal plate 4 and welded to the electrode. Welded part 5B
The bending angle (α) of is an obtuse angle. The lead tab 5 shown in the figure is bent at the boundary of the welded portion 5B, and is also bent at an obtuse angle inside. Thus, in the case where the end portion of the lead tab 5 is bent at two places, the middle of the lead tab 5 can be made straight. Although not shown, the lead tab does not need to be bent at two points even in the vicinity of the welded part. For example, the boundary with the welded part should be bent at an obtuse angle, and the entire part should be loosely bent into an arch shape. It can also be bent and welded at both ends to the battery electrodes. Welded portion 5B provided by bending the end portion of the lead tab
Are spot welded to the + and-electrodes of the cell.

The lead tab 5 having branched end portions has a feature that spot welding can be performed efficiently. That is, when the points A and B are brought into contact with the electrodes in FIG. 7 and spot welding is performed,
This is because the reactive current I flowing in the circuit shown by the broken line can be reduced and a large current can flow through the welded portion 5B and the electrode of the unit cell.

Further, the lead tab 5 can use a clad material in which different metals are laminated to reduce the reactive current during spot welding. The clad material is formed by laminating a low-conductivity metal layer having lower electrical conductivity than copper on the surface of copper. FIG. 9 shows an enlarged cross-sectional view of a clad material which is most suitable for the lead tab 5. The clad material in this figure has nickel layers as low conductivity metal layers laminated on both sides of copper. Nickel and copper are alloyed and joined at the interface. The clad material in this figure has a thick nickel layer on the surface to be welded to the electrode and a thin nickel layer on the opposite surface. The thickness of the thick nickel layer on the surface to be welded to the electrode is designed to be, for example, 0.1 to 0.25 mm, and the thin nickel layer on the opposite surface is designed to be, for example, 0.02 to 0.1 mm. The thickness of the copper laminated in the middle is, for example, 0.1 to
It is designed to be 0.4 mm. The lead tab 5 for passing an electric current of several tens of amperes preferably has a copper thickness of 0.2 mm, a thick nickel layer on the surface to be welded to the electrode is 0.2 mm, and a thick nickel layer on the opposite surface is 0.05 mm. . The lead tab 5, which is the clad material having the cross-sectional structure of FIG. 9, can be spot-welded with copper in the middle. This is because, when the lead tab is spot-welded, the nickel layer is not melted by the heat of welding, and copper is welded to the electrode.

Further, the lead tab 5 shown in FIG. 7 has an adhesive press-fitting hole 12 between the bent portions of the ends. The adhesive press-fitting hole 12 is a hole for injecting an adhesive into the back surface of the lead tab 5. In the lead tab 5 without the adhesive press-fit hole 12, the adhesive to be injected on the back surface of the lead tab 5 spot-welded to the electrode cannot be confirmed. As shown in FIG. 10, the back surface of the lead tab 5 needs to be filled with an adhesive without a gap. This is because the surface of the lead tab 5 is completely covered and shielded from air. In the lead tab 5 without the adhesive press-fitting hole 12, it takes time to inject the adhesive without leaving a gap on the back surface of the lead tab 5. In addition, it is difficult to tell whether or not the injection was possible without any gap. The lead tab 5 having the adhesive press-fitting hole 12 is filled with the adhesive from the backside of the lead tab 5. The injected adhesive is filled into the back surface of the lead tab 5 without any gap, and then leaks from both sides of the lead tab 5 to cover the lead tab 5. In other words, when the adhesive leaks from the back side of the lead tab 5, the back side of the lead tab 5 is filled with the adhesive without a gap.

In the lead tab 5 shown in FIG. 7, the adhesive press-fitting holes 12 are arranged between the bent portions. The lead tab 5 of this structure has a feature that the adhesive press-fitting hole 12 does not reduce the strength of the bent portion of the lead tab 5. The bent portion of the lead tab 5 is easily damaged by vibration. The vibration resistance strength of the bent portion is also enhanced by setting the bending angle (α) to an obtuse angle, as shown in FIG. In the lead tab 5 bent at a right angle, a large stress remains in the bent portion, which reduces the vibration resistance strength. As shown in FIG. 8, the lead tab 5 bent at an obtuse angle has a feature that the stress remaining inside is small and the vibration resistance strength can be increased.

Further, the lead tab 5 shown in FIG. 8 is covered with a covering tube 11. The covering tube 11 covers the middle portion of the lead tab 5. The lead tab 5 has an end portion not covered with the covering tube 11 covered with an adhesive. The lead tube 5 with the covering tube 11 and the adhesive.
Covers the entire surface in a completely watertight structure. As the coating tube 11, any tube that can shield the lead tab 5 from the outside air can be used, but the most suitable one is a heat shrink tube. The heat-shrinkable tube can be adhered to the surface of the lead tab 5 by heating after inserting the lead tab 5. Figure 8
The lead tab 5 shown in (1) covers a part of the bent part and does not cover the part of the adhesive press-fitting hole 12.

The lead tab 5 shown in FIG. 8 is spot welded to the + electrode of the unit cell, and FIGS.
The structure of the portion connected to the negative electrode is shown in FIGS. 10 and 12 are cross-sectional views cut in the direction of the lead tab 5, and FIGS. 11 and 13 are cross-sectional views in the direction orthogonal to this. In the batteries shown in these figures, the case 13 is arranged on the seal plate 4. A plan view of the case 13 is shown in FIG. The case 13 shown in this figure is a plastic molded product, and has a shape in which twelve disks 13A are connected so as to form a gap. The disk 13A has a circular shape slightly larger than the outer diameter of the unit cell. A cylinder 13B for inserting the unit cell is integrally formed on the lower surface of the disk 13A. The cylinder 13B has a lower end opened so that a unit cell can be inserted therein.

The disk 13A of the case 13 has an adhesive filling hole 14 at the center. The adhesive filling hole 14 is provided with a guide wall 15 on the periphery. However, the guide wall 15
Are provided on a portion of the lead tab 5 excluding the lower surface.
The guide wall 15 is provided so as to extend into the adhesive filling hole 14 of the adjacent disk 13A in order to guide the lead tab 5 to a fixed position. The case 13 having the guide wall 15 can set the lead tab 5 at an accurate position and can prevent the lead tab 5 from being displaced.

The cases 13 are arranged at both ends of the unit cells 1 and connect the twelve unit cells 1 at fixed positions. Since the cases 13 located at both ends of the unit cell 1 are connected to each other,
The connecting rod 16 is integrally formed in the gap of the disk 13A. The unit cell 1 to which the seal plate 4 is adhered is inserted and connected to the tube 13B of the case 13.

The lead tab 5 has a bent portion with a case 13
Is inserted into the adhesive filling hole 14 and the electrode through hole 4A of the seal plate 4, and the welded portion 5B is spot-welded to the + electrode of the unit cell. The end portion of the lead tab 5 not covered with the covering tube 11 is embedded and covered with the adhesive agent 6 applied to the adhesive agent filling hole 14 and the electrode through hole 4A. The adhesive 6 on the back surface of the lead tab 5 is injected from the adhesive press-fitting hole 12 of the lead tab 5. The adhesive 6 is also applied to the upper surface of the lead tab 5. The adhesive 6 includes an adhesive filling hole 14 and an electrode through hole 4A.
Is filled with and covers the entire protruding portion of the coating tube 11 of the lead tab 5.

The battery shown in FIG. 1 has the negative side sealed with the same structure as the positive side. The battery shown in this figure is provided with a safety valve on the + side. For this reason, it is not always necessary to bond the seal plate to the negative electrode end surface without the safety valve via the pressure release adhesive layer. A seal plate can be attached to the negative electrode end surface through an adhesive that does not separate even when pressure is applied. The structure in which the sealing plates are adhered to the electrode end surfaces of the + and-both ends of the battery with the pressure release adhesive layers has the feature that the both ends of the battery can be made the same structure, so that mass production can be performed efficiently.

[0036]

In the rust-proof structure battery of the present invention, the unit cell is covered with the heat-shrinkable tube, the seal plate and the adhesive in a waterproof structure. In the battery having this structure, each of the unit cells has a waterproof structure, and the surface of each unit cell can be air-cooled by the outside air, and further, the unit cell can be directly air-cooled to prevent moisture from contacting the unit cell. As described above, a battery that can be waterproofed by directly cooling each of the unit cells in an air-cooled state has an advantage that it can be cooled very efficiently as compared with the conventional case where a plurality of unit cells are housed in a sealed case. This is because the substantial air-cooling area with respect to the capacity is considerably large, and moreover, the air-cooling can be performed directly from the surface of the unit cell. As described above, the battery of the present invention that can be efficiently air-cooled as a waterproof structure has a feature that it can be discharged with a large current or charged with a large current to suppress the temperature rise of the battery and prevent the deterioration of the battery performance due to the temperature rise. is there. In addition, since each unit cell has a waterproof structure, it has the feature that it can minimize the occurrence of electrolytic corrosion due to water invading inside.

Furthermore, the rustproof structure battery of the present invention is
Even though the unit cell can be completely covered with a waterproof structure, when the safety valve opens, the gas inside the cell can be exhausted. That is, the battery of the present invention has a heat-shrinkable tube that covers the outer peripheral side surface of a unit cell, extends to the peripheral edge portion of the electrode end surface of the safety valve, and has a pressure release adhesive layer on the surface of the heat-shrinkable tube located at the peripheral edge of the electrode end surface. This is because the seal plate is adhered via. When the safety valve opens and the pressure between the seal plate and the unit cell becomes high, the pressure-seal adhesive layer peels off the seal plate, which is adhered to the heat-shrink tube through the pressure-peel adhesive layer. A gap is formed between the heat-shrinkable tube and the heat-shrinkable tube, and the pressurized gas in the electrode is exhausted from this gap. Therefore, the electrode of the present invention has a feature that the unit cell can be waterproofed and effectively air-cooled without interfering with the differential of the safety valve.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing a specific example of a rust-proof structure battery according to an embodiment of the present invention.

FIG. 2 is a perspective view of a battery having a rust preventive structure shown in FIG.

FIG. 3 is an exploded perspective view of a + electrode portion of the rust-proof structure battery shown in FIG.

FIG. 4 is a sectional view of a unit cell having a built-in safety valve.

FIG. 5 is a perspective view showing a specific example of a battery pack in which a plurality of batteries are connected.

6 is a plan view of the battery pack shown in FIG.

FIG. 7 is a plan view showing another shape of the lead tab.

8 is a side view and a plan view showing a state in which a covering tube is attached to the lead tab shown in FIG.

FIG. 9 is an enlarged sectional view of a lead tab.

FIG. 10 is an enlarged cross-sectional view of the + side main part of the battery to which the lead tab shown in FIG. 7 is connected.

11 is a sectional view in a direction orthogonal to the sectional view of FIG.

FIG. 12 is an enlarged cross-sectional view of the negative side of the battery to which the lead tab shown in FIG. 7 is connected.

13 is a sectional view in a direction orthogonal to the sectional view of FIG.

FIG. 14 is a plan view of the case shown in FIGS.

[Explanation of symbols]

1 ... Unit cell 1A ... Outer peripheral side surface 1B
Electrode end face 2 Heat shrinkable tube 3 Pressure release adhesive layer 4 Seal plate 4A Electrode through hole 5 Lead tab 5A Branch part 5B
... Welded part 6 ... Adhesive 7 ... Safety valve 8 ... Ring 9 ... Honeycomb core 10 ... Air cooling duct 11 ... Covering tube 12 ... Adhesive press-fitting hole 13 ... Case 13A ... Disc 13
B ... Cylinder 14 ... Adhesive filling hole 15 ... Guide wall 16 ... Connecting rod

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Masayuki Toriyama 1-4-1 Chuo, Wako-shi, Saitama Inside Honda R & D Co., Ltd. (72) Inventor Yoshihiro Nakazawa 1-4-1 Chuo, Wako-shi, Saitama Incorporated company Honda R & D Co., Ltd. (72) Inventor, Shoji Nakamori 1-4-1 Chuo, Wako City, Saitama Prefecture Incorporated company Honda R & D Co., Ltd. (72) Inventor, Tsukasa Ito 2-18 Keihan Hondori, Moriguchi Inside Sanyo Electric Co., Ltd. (72) Inventor Fumi Takei 2-18 Keihan Hondori, Moriguchi City, Osaka Prefecture Sanyo Electric Co., Ltd. (72) Akihiro Furuse 2-18 Keihan Hondori, Moriguchi City, Osaka Sanyo Electric Co., Ltd. (72) Inventor Kazuhiro Kitaoka 2-18 Keihan Hon-dori, Moriguchi-shi, Osaka Sanyo Electric Co., Ltd.

Claims (4)

[Claims] 1. A battery having a rust preventive structure having the following constitution. (A) The unit cell (1) has a heat-shrinkable tube on the outer peripheral side surface (1A).
It is covered with (2). (B) The heat-shrinkable tube (2) covers the peripheral portion of the electrode end surface (1B) of the safety valve of the battery. (C) On the safety valve side electrode end face (1B), a sealing plate (4) having an electrode through hole (4A) on a heat-shrinkable tube (2) at a peripheral portion via a pressure release adhesive layer (3). Is bonded to a watertight structure. (D) The lead tab (5) is inserted into the electrode through hole (4A) of the seal plate (4) to connect the end of the lead tab (5) to the electrode on the safety valve side. (E) An adhesive (6) is watertightly applied to the gap between the electrode through hole (4A) of the seal plate (4) and the lead tab (5). (F) Electrode end face (1B) opposite to safety valve side electrode end face (1B)
Are coated in a watertight structure. 2. The lead tab (5) is covered with a covering tube (11), and an adhesive press-fitting hole (12) is opened at an end of the lead tab (5) protruding from the covering tube (11), This adhesive press-fit hole (12) is a lead tab (5) welded to the electrode.
The battery having a rust preventive structure according to claim 1, wherein the surface of the lead tab (5) located near the welded part (5B) of the above and protruding from the covering tube (11) is watertightly covered with an adhesive (6). 3. The battery having a rust preventive structure according to claim 1, wherein the lead tab (5) is a clad material formed by laminating copper and a low-conductivity metal layer having electric conductivity lower than that of copper. 4. The protection according to claim 1, wherein the end portion of the lead tab (5) is bent to provide a welded portion (5B), and the bend angle (α) of the welded portion (5B) is an obtuse angle. Rust structure battery.