JP4090167B2 - Storage battery and manufacturing method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention provides a battery case having an opening that also serves as a terminal of one electrode, a sealing body that also serves as a terminal of the other electrode that seals the opening, and at least one end of positive and negative electrodes accommodated in the battery case In particular, the present invention relates to a storage battery including an electrode body having a current collector connected to a portion thereof, and a method for manufacturing the same, and in particular, to a current collector of a lead portion that connects a current collector connected to at least one of positive and negative electrodes and a sealing body The present invention relates to an improvement in the structure and the welding method.
[0002]
[Prior art]
In general, alkaline storage batteries such as nickel-hydride storage batteries and nickel-cadmium storage batteries interpose a separator between a positive electrode and a negative electrode, wind them in a spiral shape, and then attach a current collector to the end of the positive electrode or the negative electrode. Connected to form an electrode body, this electrode body is housed in a metal battery case, the lead part extending from the current collector is welded to the sealing body, and then the sealing body is interposed in the opening of the battery case It is configured to be hermetically sealed by mounting.
[0003]
When such alkaline storage batteries are used for applications such as electric tools and electric vehicles that charge and discharge at a high rate, electrical resistance at the lead portion connecting between the current collector and the sealing body, particularly among battery configurations. Greatly affects battery characteristics. That is, when the electrical resistance at the lead portion is large, discharging with a large current causes a problem that a large voltage drop due to the electrical resistance at the lead portion occurs and the battery voltage decreases. Therefore, in Japanese Patent No. 2762599, it is proposed to configure the lead part by using a plurality of current collecting parts, or to reduce the electrical resistance at the lead part by increasing the thickness of the current collecting part. Became.
[0004]
[Problems to be solved by the invention]
By the way, when a plurality of current collecting parts constituting the lead part are used, the number of parts is increased and the lead part is not flexible, so that it is difficult to weld the seal part and the seal part is attached to the battery case. When sealing by caulking to the opening, it becomes difficult to bend the lead portion, resulting in poor productivity. In addition, if the thickness of the current collecting parts constituting the lead portion is increased, the current that is ineffective for the welding current for resistance welding is increased, the weldability with the sealing body is deteriorated, and the sealing body is opened to the battery case. When caulking to the part and sealing, it becomes difficult to bend the lead part, resulting in a problem of poor productivity.
[0005]
On the other hand, when welding the lead part to the sealing body, after the sealing body is adjacent to the lead part rising vertically from the current collector and the welding electrode is pressed against the side surface of the lead part, the lead part is resistance-welded to the sealing body The lead portion is bent to attach the sealing body to the opening portion of the battery case, and the end portion of the opening portion is crimped to be sealed. In general, the use of a thick lead lead portion has a lower specific resistance and a lower battery internal resistance.
[0006]
However, as described above, after welding the lead portion to the sealing body, in order to attach the sealing body to the opening of the battery case, a long lead portion is used, and the lead portion is bent at the time of sealing. Thus, it is necessary to attach the sealing body to the opening of the battery case. Therefore, the length of the lead portion needs to be at least the radius of the electrode body, and in order to bend the lead portion, a thin and long lead portion must be used. A problem arises that the specific resistance increases and the internal resistance of the battery increases.
[0007]
Generally, the resistance of the current collecting component is in proportion to its length and inversely proportional to the cross-sectional area. Therefore, in order to reduce the resistance of the current collecting component, it is necessary to increase the cross-sectional area. However, a plate-like body is usually used as the current collecting component. When a plate-like body is used as a current collector component, the maximum width of a cylindrical battery is limited by the battery diameter, the maximum cross-sectional area of the current collector component is limited, and the resistance value of the current collector component is limited. There was a limit to the reduction.
[0008]
Therefore, the present invention was made to solve the above problems, using a current collector that can weld the sealing body and the current collector reliably even if the cross-sectional area is large and the length is short, It is a first object to obtain a storage battery excellent in high rate discharge performance. It is a second object of the present invention to provide a welding method capable of reliably welding the sealing body and the current collector using such current collector parts.
[0009]
[Means for Solving the Problems]
In order to achieve the first object, a storage battery according to the present invention is a lead comprising a sealing body and a current collector formed of a cylindrical body in which a central portion in a length direction is recessed inward to form a drum shape. The parts are fixedly connected. By using a lead portion made up of such a cylindrical body, together with the cross-sectional area of the lead portion (circumference of the base thickness length × circular cylinder of the circular cylinder) increases, the length of the lead portion Since it can be shortened, the resistance at the lead portion is reduced. As a result, a storage battery having reduced internal resistance and high output characteristics can be obtained.
[0010]
When the lead part is composed of a cylindrical body whose central part in the lengthwise direction is recessed inward to form a drum shape, the circumferential length of the cylindrical body rather than the width of the lead part made of a plate-like body Therefore, the cross-sectional area required for the lead portion can be easily secured, and the thickness of the base material of the cylindrical body is made thinner than the thickness of the lead portion made of a plate-like body. It becomes possible. For this reason, welding with the sealing body or the current collector is facilitated, and since the central part is formed in a drum shape recessed inward , the sealing body is crimped to the opening of the battery case. This makes it easier to manufacture this type of storage battery.
[0011]
Since this type of lead portion and the lower surface of the sealing body or the upper surface of the current collector are fixedly connected by resistance welding, the lead portion needs to have a shape and structure in which a welding electrode can be easily disposed. For this reason, in the lead of the present invention, the upper and lower end portions of the cylindrical body are provided with flange portions in which wide portions and narrow portions are alternately formed, and the wide portion of the upper end flange portion and the narrow portion of the lower end flange portion. Are arranged so as to overlap each other across a space, and the narrow portion of the upper end collar and the wide portion of the lower end collar overlap each other across the space.
As a result, the wide portion of the flange becomes a welded portion with the lower surface of the sealing body or the upper surface of the current collector, and the welding electrode can be disposed on the outer peripheral portion of the narrow portion of the flange. For this reason, welding of the wide part of the lower end collar part of the cylindrical body and the current collector or welding of the wide part of the upper end collar part of the cylindrical body and the lower surface of the sealing body is facilitated, and this type of storage battery can be easily manufactured. As a result, workability is improved.
[0012]
In addition, in order to firmly connect the lead part and the lower surface of the sealing body or the upper surface of the current collector by resistance welding, it is necessary to concentrate the welding current on the welded part. If small protrusions are formed on the upper surface of the upper surface or the lower surface of the wide portion of the lower end flange, the welding current concentrates on these small protrusions, and the lead portion and the lower surface of the sealing body or the upper surface of the current collector are It is firmly connected by resistance welding.
[0013]
In order to achieve the second object, a method of manufacturing a storage battery according to the present invention includes a lead portion composed of a cylindrical body whose central portion in the length direction is recessed inwardly to form a drum shape. A first welding step of welding to either the upper surface of the electric body or the lower surface of the sealing body, an electrolyte injection step of injecting an electrolytic solution into the battery case, and an arrangement step of disposing the sealing body in the opening of the battery case And a sealing step for sealing the sealing body to the opening of the battery case, and a current is passed between the battery case and the sealing body to weld the lead part to either the lower surface of the sealing body or the upper surface of the current collector. A second welding step.
[0014]
In this way, the lead portion composed of the cylindrical body whose longitudinal central portion is recessed inwardly to form a drum shape is welded to either the upper surface of the current collector or the lower surface of the sealing body. 1 After the welding process, the electrolyte is injected into the battery case, the opening of the battery case is sealed with the sealing body, and then a voltage is applied between the battery case and the sealing body. Since the current flows through the path of the electric body → positive / negative electrode → battery case or vice versa (second welding process), the lead portion is either one of the lower surface of the sealing body or the upper surface of the current collector. Can be welded to.
[0015]
In this case, if the sealing body and the lead portion and the lead portion and the current collector are not in close contact with each other, a phenomenon that the molten metal is scattered occurs, so-called “welding dust” occurs, which is the battery. One of the causes of a short circuit. For this reason, in the sealing process, the sealing body is pressed around the central portion in the length direction of the cylindrical body that is recessed inwardly to form a drum shape. In addition, it is necessary to bring the lead portion and the current collector into close contact with each other.
[0016]
Further, in the method for producing a storage battery according to the present invention, the lead portion formed of a cylindrical body having a drum shape with a central portion in the length direction recessed inward is formed on the upper surface of the current collector or the lower surface of the sealing body. A battery case so that a sealing body and a lead part or a lead part and a current collector are in contact with each other, a first welding process for welding to either one, an electrolyte injection process for injecting an electrolyte into the battery case And a second welding step of welding a lead portion to either the lower surface of the sealing body or the upper surface of the current collector by passing an electric current between the battery case and the sealing body. And a sealing step for sealing the sealing body to the opening of the battery case.
[0017]
In this way, even if a sealing step for sealing the sealing body to the opening of the battery case is performed after the second welding step, a voltage is applied between the battery case and the sealing body in the second welding step. Since the sealing body and the lead part or the lead part and the current collector are in contact with each other, the current flows through the sealing body, the lead part, the current collector, the positive / negative electrode, the battery case path, or the reverse path. Then, the lead portion can be welded to either the lower surface of the sealing body or the upper surface of the current collector. Thereafter, if the sealing body is sealed in the opening of the battery case in the sealing step, the battery can be formed.
[0018]
In this case, if the gap between the sealing body and the lead portion and between the lead portion and the current collector are not in close contact with each other, a phenomenon that the molten metal scatters occurs and a battery short circuit occurs. The sealing body is pressed and dented inward so as to be crushed around the central part in the length direction of the cylindrical body , and a current flows between the battery case and the sealing body. Thus, it is necessary to make contact between the sealing body and the lead portion and between the lead portion and the current collector.
[0019]
Then, the wide portion and the narrow portion is provided with a flange portion formed alternately at the upper and lower ends of the cylindrical body, and the narrow portion of the wide portion of the upper flange portion of the cylindrical body and the lower flange portion is a space therebetween mutually overlap, and a wide portion of the narrow portion of the upper flange portion of the cylindrical body and the lower flange portion is disposed so as to overlap each other with a space, the outer peripheral portion of the narrow portion of the upper flange portion Te Place the welding electrode and weld the wide part of the lower end collar part to the upper surface of the current collector, or arrange the welding electrode on the outer periphery of the narrow part of the lower end collar part and place the wide part of the upper end collar part and when so welding the lower surface of the sealing member, it becomes possible to arrange the welding electrodes on the outer periphery of the narrow portion of the upper flange portion of the cylindrical body, and the wide portion of the lower flange portion of the cylindrical body collecting The work at the time of welding the electric body is facilitated, the manufacture of this type of storage battery is facilitated, and the workability is improved.
[0020]
Further, in order to firmly fix and connect the lead portion and the lower surface of the sealing body or the upper surface of the current collector in the second welding described above, it is necessary to concentrate the welding current on the welded portion. For this reason, it is necessary to form small protrusions on at least one of the upper surface of the wide portion of the upper end flange or the lower surface of the wide portion of the lower end flange, and concentrate the welding current on the small protrusion.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Below, an embodiment at the time of applying the present invention to a nickel-hydrogen storage battery is described based on figures. FIG. 1 is a cross-sectional view showing a state in which a cylindrical body constituting the lead portion of the present invention is welded to a positive electrode current collector and a sealing body. FIG. 2 is a cross-sectional view showing a state where the electrode body is inserted into the battery case and the cylindrical body and the sealing body are welded. Further, FIG. 3 is a view showing a main part in a state where a cylindrical body is welded to the upper part of the positive electrode current collector of the electrode body, FIG. 3 (a) is a top view thereof, and FIG. FIG. 3C is a cross-sectional view taken along the line AA of FIG. FIG. 4 is a cross-sectional view showing a state in which the plate-like body constituting the lead portion of the comparative example is welded to the positive electrode current collector and the sealing body.
[0022]
1. Electrode Body The nickel-hydrogen storage battery of this embodiment includes a nickel positive electrode plate 11 and a hydrogen storage alloy negative electrode plate 12. The nickel positive electrode plate 11 is formed by forming a nickel sintered porous body on the surface of an electrode plate core made of punching metal, and then filling the nickel sintered porous body with an active material mainly composed of nickel hydroxide by a chemical impregnation method. Have been made. On the other hand, the hydrogen storage alloy negative electrode plate 12 is prepared by filling the surface of an electrode plate core made of punching metal with a paste-like negative electrode active material made of hydrogen storage alloy, drying, and rolling to a predetermined thickness. Has been.
[0023]
A separator 13 was interposed between the nickel positive electrode plate 11 and the hydrogen storage alloy negative electrode plate 12, and a spiral electrode group was prepared by winding the separator 13 in a spiral shape. An end portion 11a of a punching metal that is an electrode plate core body of the nickel positive electrode plate 11 is exposed at the upper end surface of the spiral electrode group, and an electrode plate core body of the hydrogen storage alloy negative electrode plate 12 is exposed at the lower end surface. An end portion 12a of a punching metal is exposed. The positive electrode core exposed at the upper end surface of the spiral electrode group has a large number of openings 14a, 14a,... And a liquid injection opening 14b (see FIG. 3A), and is a disk-shaped positive current collector. 14 was welded, and a disk-shaped negative electrode current collector 15 having a large number of openings (not shown) was welded to the negative electrode core exposed at the lower end surface to produce a spiral electrode body 10.
[0024]
2. Lead Part Next, a cylindrical body 20 serving as a lead part for conductively connecting the positive electrode current collector 14 and the sealing body 17 is prepared. The cylindrical body 20 is composed of a body portion 21 having a drum shape with a central portion in the length direction being recessed inward, and flanges 22 and 23 formed on the upper and lower ends of the body portion 21. The Wide width portions 22 a and narrow portions 22 b are alternately formed on the upper end flange portion 22, and wide portions 23 a and narrow portions 23 b are alternately formed on the lower end flange portion 23.
And the wide part 22a of the upper end collar part 22 and the narrow part 23b of the lower end collar part 23 overlap each other across a space, and the narrow part 22b of the upper end collar part 22 and the wide part 23a of the lower end collar part 23 Are arranged so as to overlap each other across a space. A small protrusion 22 c is formed on the upper surface of the wide portion 22 a of the upper end flange portion 22. The cylindrical body 20 has a peripheral wall thickness of 0.3 mm, a minimum inner diameter of 14.8 mm, and a maximum outer diameter of 19.2 mm.
[0025]
3. Nickel-hydrogen storage battery (1) Example 1
When assembling the nickel-hydrogen storage battery, first, the cylindrical body 20 described above is placed on the positive electrode current collector 14, and then a welding electrode (not shown) is provided on the outer peripheral portion of the narrow portion 22b of the upper end collar. It arrange | positioned and the wide part 23a of the lower end collar part and the collector 14 were spot-welded. Thereafter, the electrode body 10 in which the cylindrical body 20 was welded to the positive electrode current collector 14 was housed in a bottomed cylindrical battery case 16 in which iron was nickel-plated (the outer surface of the bottom surface serves as a negative electrode external terminal).
[0026]
Next, a vibration isolating ring 18 was inserted into the upper inner peripheral side of the battery case 16, and a groove was formed on the outer peripheral side of the battery case 16 to form a recess 16 a at the upper end of the vibration isolating ring 18. Thereafter, an electrolytic solution made of a 30% by mass potassium hydroxide (KOH) aqueous solution was injected into the battery case 16. Next, the bottom surface of the sealing body 17 was arranged on the upper part of the opening of the battery case 16 so as to contact the upper end flange 22 of the cylindrical body 20. The sealing body 17 includes a lid body 17a formed with a circular downward projecting portion on the bottom surface, a positive electrode cap (positive electrode external terminal) 17b, and a spring 17c interposed between the lid body 17a and the positive electrode cap 17b. And a valve plate 17d. A gas vent hole is formed in the center of the lid 17a.
[0027]
After the sealing body 17 is disposed as described above, one welding electrode W1 is disposed on the upper surface of the positive electrode cap (positive electrode external terminal) 17a, and the other welding electrode is disposed on the lower surface of the bottom surface (negative electrode external terminal) of the battery case 16. W2 was placed. Thereafter, while applying a pressure of 2 × 10 ⁶ N / m ² between the pair of welding electrodes W1 and W2, a voltage of 24V is applied between the welding electrodes W1 and W2 in the discharge direction of the battery, and 3KA Was applied for about 15 msec. By this energization process, current concentrates on the contact portion between the bottom surface of the sealing body 17 and the small protrusion 22c formed on the wide portion 22a of the upper end flange portion 22 of the cylindrical body 20, and the small protrusion 22c and the sealing body 17 The bottom surface was welded to form a weld. At the same time, the contact portion between the lower surface of the negative electrode current collector 15 and the upper surface of the bottom surface (negative electrode external terminal) of the battery case 16 was welded to form a welded portion.
[0028]
Next, an insulating gasket 19 is fitted on the periphery of the sealing body 17, and a pressure is applied to the sealing body 17 using a press machine, and the sealing body 17 is placed in the battery case until the lower end of the insulating gasket 19 is positioned at the recess 16a. 16 was pushed into. Thereafter, the opening edge of the battery case 16 was crimped inward to seal the battery, and a cylindrical nickel-hydrogen storage battery having a nominal capacity of 6.5 Ah was produced. Note that the main body 21 of the cylindrical body 20 was crushed around the recessed central portion by the applied pressure at the time of sealing. The nickel-hydrogen storage battery of Example 1 produced in this way was designated as battery A.
[0029]
(2) Example 2
First, after the cylindrical body 20 described above is placed on the positive electrode current collector 14, a welding electrode (not shown) is disposed on the outer peripheral portion of the narrow portion 22b of the upper end flange 22, and the lower end flange 23 is disposed. The wide portion 23a and the current collector 14 were spot welded. Thereafter, the electrode body 10 in which the cylindrical body 20 was welded to the positive electrode current collector 14 was housed in a bottomed cylindrical battery case 16 in which iron was nickel-plated (the outer surface of the bottom surface serves as a negative electrode external terminal).
[0030]
Next, a vibration isolating ring 18 was inserted into the upper inner peripheral side of the battery case 16, and a groove was formed on the outer peripheral side of the battery case 16 to form a recess 16 a at the upper end of the vibration isolating ring 18. Thereafter, an electrolytic solution made of a 30% by mass potassium hydroxide (KOH) aqueous solution was injected into the battery case 16. Next, the bottom surface of the sealing body 17 was arranged on the upper part of the opening of the battery case 16 so as to contact the upper end flange 22 of the cylindrical body 20. The sealing body 17 has the same configuration as the sealing body 17 of the first embodiment described above.
[0031]
Next, an insulating gasket 19 is fitted on the periphery of the sealing body 17, and a pressure is applied to the sealing body 17 using a press machine, and the sealing body 17 is placed in the battery case until the lower end of the insulating gasket 19 is positioned at the recess 16a. 16 was pushed into. Thereafter, the opening edge of the battery case 16 was crimped inward to seal the battery. Note that the main body portion 21 of the cylindrical body 20 was crushed around the central portion recessed inward by the applied pressure at the time of sealing. Next, one welding electrode W1 was arranged on the upper surface of the positive electrode cap (positive electrode external terminal) 17a, and the other welding electrode W2 was arranged on the lower surface of the bottom surface (negative electrode external terminal) of the battery case 16.
[0032]
Thereafter, while applying a pressure of 2 × 10 ⁶ N / m ² between the pair of welding electrodes W1 and W2, a voltage of 24V is applied between the welding electrodes W1 and W2 in the discharge direction of the battery, and 3KA Was applied for about 15 msec. By this energization process, current concentrates on the contact portion between the bottom surface of the sealing body 17 and the small protrusion 22c formed on the wide portion 22a of the upper end flange portion 22 of the cylindrical body 20, and the small protrusion 22c and the sealing body 17 The bottom surface was welded to form a weld. At the same time, the contact portion between the lower surface of the negative electrode current collector 15 and the upper surface of the bottom surface (negative electrode external terminal) of the battery case 16 was welded to form a welded portion. Thereby, a cylindrical nickel-hydrogen storage battery having a nominal capacity of 6.5 Ah was produced, and battery B of Example 2 was obtained.
[0033]
(3) Comparative Example As shown in FIG. 4, the positive electrode core exposed on the upper end surface of the spiral electrode group produced in the same manner as in Example 1 described above has a large number of openings, and leads 14b from a part thereof. The disk-shaped positive electrode current collector 14a with a stretched line was welded. On the other hand, a disc-shaped negative electrode current collector 15 having a large number of openings was welded to the negative electrode core exposed at the lower end surface of the spiral electrode group to produce a spiral electrode body. This electrode body is accommodated in the battery case 16, and the negative electrode current collector 15 is spot welded to the inner bottom surface of the battery case 20 (in FIG. 4, the welding electrode is inserted into the center of the wound electrode body). 4 does not exist, but FIG. 4 is a diagram schematically showing that there is actually a space for inserting a welding electrode). Thereafter, the vibration isolating ring 18 was inserted into the upper inner peripheral side of the battery case 16, and grooving was performed on the outer peripheral side of the battery case 16 to form a recess 16 a at the upper end portion of the vibration isolating ring 18.
[0034]
Next, after the lead portion 14 b extended from the positive electrode current collector 14 a was bent vertically, the end portion of the lead portion 14 b was resistance welded to the bottom surface of the sealing body 17. Next, after injecting an electrolytic solution made of a 30 mass% potassium hydroxide (KOH) aqueous solution into the battery case 16, the lead part 14b is bent, and the sealing body 17 having the insulating gasket 19 fitted on the periphery thereof is formed into the battery. Arranged in the opening of the case 16. Subsequently, the opening edge of the battery case 16 was crimped inward to seal the battery, and a cylindrical nickel-hydrogen storage battery having a nominal capacity of 6.5 Ah was produced. The nickel-hydrogen storage battery of the comparative example produced in this way was designated as battery X.
[0035]
4). Battery Characteristic Test (1) Activation Using the batteries A and B of Examples 1 and 2 and the battery X of Comparative Example produced as described above, 650 mA (0.1 C) at room temperature (ambient temperature 25 ° C.) The battery was charged for 8 hours at a current value of 1 hour, paused for 1 hour, and then discharged at a current value of 1300 mA (0.2 C) until the battery voltage reached 0.8 V. This charge / discharge cycle was The battery was activated 10 times repeatedly.
[0036]
(2) VI characteristic test Next, using the batteries A and B of Examples 1 and 2 activated as described above and the battery X of Comparative Example, 1300 mA (2C) at room temperature (ambient temperature 25 ° C.) The battery was discharged at a current value of 1300 mA (0.2 C) for 3 hours at a current value of 1300 mA (0.2 C). After resting for 1 hour, the battery was discharged for 30 seconds at a current value of 25 A, and the battery voltage 10 seconds after the start of discharge was measured.
Then, after charging the power for the discharged capacity, similarly, the battery was discharged at current values of 50A, 70A, and 100A for 30 seconds, and the battery voltage 10 seconds after the start of discharge was measured. When the VI voltage (VI characteristics) is obtained with the vertical axis representing the battery voltage 10 seconds after the start of discharge thus obtained and the horizontal axis representing each current value, the results shown in FIG. became.
[0037]
As can be seen from FIG. 5, the slope of the V-I straight line of the batteries A and B of Examples 1 and 2 is small while the slope of the V-I straight line of the battery X of the comparative example is large. From this, it can be seen that the operating voltages of the batteries A and B of Examples 1 and 2 are both high and the battery internal resistance is low. In the batteries A and B of Examples 1 and 2, the cylindrical body 20 serving as the lead portion has a large cross-sectional area in the current collecting direction and a short length (height) in the current collecting direction. It is considered that the internal resistance at the point was reduced and high output characteristics were obtained. Further, since the internal resistance at the lead portion is low, the voltage drop is also reduced, and the operating voltage is considered to be high.
[0038]
In the embodiment described above, a voltage of 24 V is applied in the battery discharge direction between the positive electrode cap (positive electrode external terminal) 17a and the bottom surface (negative electrode external terminal) of the battery case 16, and a current of 3 KA is applied for about 15 msec. Although welding was performed while flowing, there was no correlation in the direction of the current applied to the battery, and similar results were obtained regardless of whether the battery was discharged or charged. In addition, regarding the applied current value, the same effect was obtained at 300 A or more regardless of the size of the battery. Note that a direct current or an alternating current power source can be used as a power source for welding current flowing between the battery case and the sealing body.
[0039]
However, when an extremely excessive current is applied, the cylindrical body 20 is melted even when applied for a short time, and the upper limit value of the current value to be melted varies depending on the material and shape of the cylindrical body 20. The current value must be a value that is 300 A or more and that the hourglass tube 20 does not melt. Furthermore, if the application time is 0.25 msec or more, the same effect can be obtained. However, if the application time is as long as 1 second, the cylindrical body 20 is melted, which is not preferable.
[0040]
In the above-described embodiment, after the cylindrical body 20 is welded to the positive electrode current collector 14 side, a current is applied between the positive electrode external terminal (positive electrode cap) 17a and the negative electrode external terminal (bottom surface of the battery case 16). The cylindrical body 20 and the sealing body 17 are welded to each other, but after the sealing body 17 and the cylindrical body 20 are welded, the positive electrode external terminal (positive electrode cap) 17a and the negative electrode external terminal (the bottom surface of the battery case 16). A similar effect can be expected even when a current is passed between the positive electrode current collector 14 and the cylindrical body 20. In this case, it is necessary to provide a small protrusion on the lower surface of the wide portion 23 a of the lower end flange 23 of the cylindrical body 20.
[0041]
In the above-described embodiment, a current is passed between the positive electrode external terminal (positive electrode cap) and the negative electrode external terminal (bottom surface of the battery case) to weld the sealing body and the current collector and to collect the negative electrode current collector. The example in which the body and the inner bottom surface of the battery case are welded at the same time has been described. After spot welding the negative electrode current collector and the inner bottom surface of the battery case, the positive electrode external terminal (positive electrode cap) and the negative electrode external terminal The sealing member and the current collector may be welded by passing an electric current between them (the bottom surface of the battery case).
In this case, it is necessary to provide a space for inserting a welding electrode at the center of the spiral electrode body 10, and this space is formed by a core trace space when forming the spiral electrode group. Good.
[0042]
Further, in the above-described embodiment, the example in which the sealing body is the positive electrode terminal and the battery case is the negative electrode terminal has been described. However, the sealing body may be the negative electrode terminal and the battery case may be the positive electrode terminal. In this case, the positive electrode current collector is welded to the inner bottom surface of the battery case, and the bottom surface of the sealing body is welded to the negative electrode current collector through the cylindrical body 20.
Furthermore, in the above-described embodiment, an example in which the present invention is applied to a nickel-hydrogen storage battery has been described. However, the present invention is not limited to a nickel-hydrogen storage battery, but may be applied to other storage batteries such as a nickel-cadmium storage battery. Obviously we can do it.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing a state in which a cylindrical body constituting a lead portion of the present invention is welded to a positive electrode current collector and a sealing body.
FIG. 2 is a cross-sectional view showing a state in which an electrode body is inserted into a battery case and a cylindrical body and a sealing body are welded.
FIG. 3 is a view showing a main part in a state where a cylindrical body is welded to the upper part of a positive electrode current collector of an electrode body, FIG. 3 (a) shows a top view thereof, and FIG. 3 (b) shows a side view thereof. FIG. 3C is a cross-sectional view showing the AA cross section of FIG.
FIG. 4 is a cross-sectional view showing a storage battery of a conventional example (comparative example), in which a lead part is welded to a sealing body.
FIG. 5 is a diagram showing voltage (V) -current (I) characteristics of each battery.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Electrode body, 11 ... Positive electrode plate, 12 ... Negative electrode plate, 13 ... Separator, 14 ... Positive electrode collector, 15 ... Negative electrode collector, 16 ... Battery case (negative electrode external terminal), 16a ... Groove part, 17 ... Sealing Body, 17a ... Lid, 17b ... Positive electrode cap (positive electrode external terminal), 18 ... Anti-vibration ring, 19 ... Insulating gasket, 20 ... Cylindrical body (lead part), 21 ... Body part, 22, 23 ... Gutter part, 22a , 23a ... Wide part, 22b, 23b ... Narrow part, W1, W2 ... Welding electrode

Claims (11)

Meanwhile a battery case having an opening serving as a pole of terminals, and a sealing body serving as a terminal of the other electrode to seal said opening, collecting at least one end of the positive and negative electrode housed in the battery case A storage battery comprising an electrode body to which an electric body is connected,
The storage battery is characterized in that the sealing body and the current collector are fixedly connected to each other by a lead portion composed of a cylindrical body having a central portion in the length direction that is recessed inward to form a drum shape . The upper and lower ends of the cylindrical body are provided with ridges in which wide portions and narrow portions are alternately formed, and the wide portions of the upper end ridges and the narrow portions of the lower end ridges overlap each other across a space. The storage battery according to claim 1, wherein the narrow portion of the upper end collar and the wide portion of the lower end collar overlap each other with a space therebetween.   3. The storage battery according to claim 2, wherein a small protrusion is formed on at least one of an upper surface of the wide portion of the upper end flange portion or a lower surface of the wide portion of the lower end flange portion.   The storage battery according to claim 3, wherein the small protrusion is fixedly connected to a lower surface of the sealing body or an upper surface of the current collector. It said cylindrical body storage battery according to any one of claims 1 to 4, characterized in that they are crushed and pressed around the central portion of its length. In a battery case having an opening that also serves as a terminal of one electrode, an electrode body in which a current collector is connected to at least one of the positive and negative electrodes is accommodated, and then the opening serves as a terminal of the other electrode A method of manufacturing a storage battery formed by sealing with a sealing body,
1st welding which welds the lead part comprised from the cylindrical body by which the center part of the length direction was dented inwardly, and was made into the drum shape to either the upper surface of the said electrical power collector, or the lower surface of the said sealing body Process,
An electrolyte injection step of injecting an electrolyte into the battery case;
An arrangement step of arranging the sealing body in the opening of the battery case;
A sealing step of sealing the sealing body in the opening of the battery case;
A second welding step in which a current is passed between the battery case and the sealing body to weld the lead portion to either the lower surface of the sealing body or the upper surface of the current collector. A method for manufacturing a storage battery. The method for manufacturing a storage battery according to claim 6, wherein, in the sealing step, the sealing body is pressed and crushed around a central portion in a length direction of the cylindrical body . In a battery case having an opening that also serves as a terminal of one electrode, an electrode body in which a current collector is connected to at least one of the positive and negative electrodes is accommodated, and then the opening serves as a terminal of the other electrode A method of manufacturing a storage battery formed by sealing with a sealing body,
1st welding which welds the lead part comprised from the cylindrical body by which the center part of the length direction was dented inwardly, and was made into the drum shape to either the upper surface of the said electrical power collector, or the lower surface of the said sealing body Process,
An electrolyte injection step of injecting an electrolyte into the battery case;
An arranging step of arranging the sealing body in the opening of the battery case so that the sealing body and the lead portion or the lead portion and the current collector are in contact with each other;
A second welding step in which a current is passed between the battery case and the sealing body to weld the lead portion to either the lower surface of the sealing body or the upper surface of the current collector;
A method for producing a storage battery, comprising: a sealing step of sealing the sealing body in an opening of the battery case. The method for manufacturing a storage battery according to claim 8, wherein in the second welding step, the sealing body is pressed and crushed around a central portion in a length direction of the cylindrical body . While having an eaves portion in which wide portions and narrow portions are alternately formed on the upper and lower ends of the cylindrical body ,
And the wide portion of the width narrow portion of the wide end and the lower flange portion of the upper flange portion of the drum-shaped cylindrical body overlap each other with a space, and the narrow part of the upper flange portion of the cylindrical body and the lower flange portion Are arranged so as to overlap each other across a space,
A welding electrode is arranged on the outer peripheral portion of the narrow portion of the upper end flange, and the wide portion of the lower end flange and the upper surface of the current collector are welded, or the outer peripheral portion of the narrow portion of the lower end flange The method for manufacturing a storage battery according to any one of claims 6 to 9, wherein a welding electrode is disposed on the wide end of the upper end flange and the lower surface of the sealing body is welded. .   A small protrusion is formed on at least one of the upper surface of the wide portion of the upper end flange or the lower surface of the wide portion of the lower end flange, and a welding current is concentrated on the small protrusion so that the small protrusion and the lower surface of the sealing body or The method for manufacturing a storage battery according to claim 10, wherein the small protrusion and the upper surface of the current collector are welded.

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