Sealed battery and battery jacket can

Abstract

There is provided a sealed battery having excellent corrosion resistance and sealing performance. The sealed battery 1 includes a battery jacket can 2 having a bottom and being in a cylindrical or polyhedral shape. The battery jacket can 2 also serves as a collector of one of the electrodes. The battery jacket can 2 has an opening pointing upwards and accommodates active parts (3, 4, 5 and 20). The opening is sealed by a sealing part 10 that includes a flat metal sealing plate 6, a gasket 9 made of an insulator, and a terminal part 7 of the other electrode. In the sealing part, the terminal part is attached to the sealing plate 6 using the gasket 9. The sealing plate has a planar shape that matches a shape of the opening of the battery jacket can. The sealing plate is in a saucer shape whose edge section is bent upwards. An upper end of the edge section of the sealing plate is laser-welded to an upper end of the battery jacket can while the sealing plate being inserted inside the opening of the battery jacket can. The battery jacket can is made of ferritic stainless steel to which Tin (Sn) is added.

Claims

1. A sealed battery, comprising: a battery jacket can that has a bottom and is in a cylindrical or polyhedral shape, that also a current collector of a first one of two electrodes, that has an opening pointing upwards and defines an upper end, and that is made of ferritic stainless steel to which Tin (Sn) is added; an active parts that are accommodated in the battery jacket can; and a sealing part that includes a metal sealing plate, a gasket made of an insulator, and a terminal part of the other electrode, that seals the opening of the battery jacket can, and in which the terminal part is attached to the sealing plate using the gasket, the sealing plate being in a saucer shape whose edge section is bent upwards to define an upper edge and conforms to the shape of the opening of the battery jacket can at the upper end of the battery jacket can, the upper end of the edge section of the sealing plate being laser-welded to the upper end of the battery jacket can with the sealing plate being disposed inside the opening of the battery jacket can.

2. A sealed battery according to claim 1, wherein the sealing plate is made of Sn-added ferritic stainless steel.

3. A sealed battery according to claim 1, wherein the sealed battery is a primary battery whose cathode active material is manganese dioxide and whose anode active material is lithium or lithium alloy.

4. A battery jacket can included in a sealed battery according to claim 1, the battery jacket can having a bottom and being in a cylindrical or polyhedral shape, wherein the battery jacket can is made of Tin (Sn)-added ferritic stainless steel.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a diagram showing the construction of a sealed battery of the embodiment according to the present invention.

(2) FIG. 2 is an enlarged view of a part of a sealed battery sealed by crimping.

(3) FIG. 3 is a diagram illustrating how to evaluate the sealing performance realized by laser welding.

(4) FIG. 4 is a graph showing the sealing performance in the embodiment.

DESCRIPTION OF EXEMPLARY EMBODIMENTS

(5) The embodiment of the invention will be described below with reference to the accompanying drawings. In the description below, the same or similar items will be indicated by the same symbols and duplicate descriptions will be often omitted. In some drawings, symbols unnecessary for the explanation will be omitted.

(6) Embodiment

(7) As a sealed battery of the embodiment according to the present invention, a lithium primary battery is provided. As well known, lithium primary batteries whose cathode active material is manganese dioxide and whose anode active material is lithium or lithium alloy have high energy density. And such lithium primary batteries can discharge for a long period of time, and the voltage drop is small until the end stage of discharge. The lithium primary batteries are therefore widely used in power supplies of devices such as a stationary gas meter, a stationary water meter and the like; that is, the batteries continue to supply power to the devices for a long period of time. Also, lithium primary batteries which have not yet been used can be stored for a long period of time without a large loss of capacity. That is, the lithium primary batteries are often used outdoors and stored for long period. And, lithium primary batteries are required to have higher corrosion resistance than other types of batteries. It goes without saying that the corrosion resistance has to be achieved with a low cost.

(8) FIG. 1 is a diagram showing the overall construction of a sealed battery 1 of the embodiment according to the present invention; a spiral-wound primary lithium battery (hereinafter referred to as the sealed battery 1) in this embodiment. The sealed battery 1 is in a cylindrical shape having an external diameter of 17 mm and a height of 45 mm, and FIG. 1 is a longitudinal sectional view when a direction in which a cylinder axis 50 extends is the up-and-down (vertical) direction. The sealed battery 1 has the following basic construction: a cylindrical metal battery jacket can(hereinafter referred to as a cell can 2) accommodates an active part composed of a positive electrode 3, a negative electrode 4, a separator 5, and an electrolyte solution 20; the cell can 2 has a bottom and serves as an anode current collector; the opening of the cell can 2 is sealed by a sealing part 10 including a metal sealing plate (hereinafter referred to as the sealing plate 6), a positive terminal 7, a metal washer (hereinafter referred to as the washer 8), and a gasket 9 made of insulating resin.

(9) The positive electrode 3 constituting the active parts is made by applying a positive electrode material to stainless steel lath before drying, the positive electrode material being in slurry form. For example, the positive electrode material is a mixture of electrolytic manganese dioxide (EMD: serving as a cathode active material), graphite (serving as electro-conductive substance) and a binder (a fluorine-based binder and the like) in a certain ratio (e.g. EMD: graphite: binder=93 wt %: 3 wt %: 4 wt %). And, the positive electrode material is formed into slurry using pure water.

(10) The negative electrode 4 is lithium metal or lithium alloy in plate form, and lithium-aluminum alloy is used in this embodiment. The negative electrode 4 and the positive electrode 3 constitute the winding structure 40 in which these electrodes are wound together with the separator 5 placed between these electrodes. A winding structure 40 is inserted into the cell can 2. The separator 5 is composed of, for example, microporous polyolefin film. On the upper and lower ends of the winding structure 40, a disc-shaped insulator 13 is placed. This prevents the negative electrode 4 from being in contact with the positive terminal 7, and also prevents the positive electrode 3 from being in contact with the cell can 2 which serves the anode current collector.

(11) The metal sealing plate 6 constituting the sealing part 10 has a disk-like shape having an opening on the center thereof. When the side of the opening end in the cell can 2 is defined as “up”, the edge of the disk is bent upwards. At the central opening of the sealing plate 6, the metal positive terminal 7 and the metal washer 8 are caulked with the resin gasket 9 placed between the terminal and the washer. For the material of the sealing plate 6 and the positive terminal 7, Ni-plated steel may be employed as in conventional sealed batteries. When laser beam irradiates the boundary part between the edge of the sealing plate 6 and the upper edge of the cell can 2 (the position indicated by the symbol 30 in the figure), the sealing plate 6 and the cell can 2 are welded together on a contact area 31 in which the sealing plate 6 and the cell can 2 are in contact with each other. The opening of the cell can 2 is thereby sealed, and the cell can 2 is sealed. And, (the lath of) the positive electrode 3 is connected to the lower surface of the positive terminal 7 through a lead tab 11, and the negative electrode 4 is connected to the inner surface of the cell can 2 through a lead tab 12. The sealed cell can 2 is filled with electrolyte solution 20. The solvent of the electrolyte solution 20 is, for example, a well-known three-component non-aqueous solution in which the proportion of propylene carbonate (PC), ethylene carbonate (EC) and 1,2-dimethoxyethane (DME) is the volume ratio of 20 vol %: 20 vol %: 60 vol %. The electrolyte solution 20 may be, for example, a solution in which lithium triflate (LiCF.sub.3SO.sub.3) is dissolved in this solvent to a concentration of 0.8 mol/l, the lithium triflate serving as a supporting electrolyte.

(12) The configuration and construction of the sealed battery 1 according to the embodiment is the same as a spiral-wound primary lithium battery which is a commercial product. But, in the sealed battery 1 of the embodiment, ferritic stainless steel to which Tin (Sn) of 0.3 wt % is added (hereinafter referred to as Sn-added ferritic stainless steel) is used as a material of the cell can 2. The cell can 2 made of Sn-added ferritic stainless steel has higher corrosion resistance and long-term storage capability, and can reduce processing time of laser welding. The section below describes sealing performance of laser welding and corrosion resistance in the sealed battery 1 according to the embodiment.

(13) Corrosion Resistance

(14) For evaluating the corrosion resistance of the sealed battery 1 according to the embodiment, prepared were samples of the sealed batteries which have the configuration shown in FIG. 1 and whose material of the cell can 2 are different. Specifically, the following two types of samples were prepared: sealed batteries each having a cell can made of Sn-added ferritic stainless steel; and sealed batteries each having a cell can made of Ni-plated steel sheet. For the material of the sealing plate 6 and the positive terminal 7, Ni-plated steel was employed as in conventional sealed batteries. Corrosion resistance test was conducted in which samples were stored at room temperature, at 60° C./90% relative humidity (RH), or at 80° C./90% RH. In 10 days, 30 days, 60 days, and 100 days after the samples were stored, the outer surfaces of the batteries were visually examined about the presence of rust. For each test, ten samples of each type were prepared.

(15) Table 1 below shows the result of the corrosion test.

(16) TABLE-US-00001 TABLE 1 The Number of Rusting Samples Test Cell can 10 days 30 days 60 days 100 days Room Ni-plated 0/10 2/10 3/10 5/10 temperature steel sheet Sn-added 0/10 0/10 0/10 0/10 60° C. 90% RH Ni-plated 2/10 5/10 7/10 8/10 steel sheet Sn-added 0/10 0/10 0/10 0/10 80° C. 90% RH Ni-plated 4/10 8/10 10/10  10/10  steel sheet Sn-added 0/10 0/10 1/10 1/10

(17) As shown in Table 1, of 10 samples whose cell cans were made of Ni-plated steel sheet, two samples rusted in 30 days after being stored at room temperature, and half of them rusted in 100 days. At temperature of 60° C. and relative humidity (RH) of 90%, two of them rusted in 10 days after being stored, and eight of them rusted in 100 days. At temperature of 80° C. and relative humidity (RH) of 90%, four of them rusted in 10 days, and all of them rusted in 100 days. As shown in the test result, whereas samples whose cell cans are made of Ni-plated steel sheet maintain corrosion resistance at room temperature for a short period, rust occurs under severe environmental conditions or during long-term storage; the rust may be caused by pin holes which are produced during shaping of the cell can.

(18) On the other hand, all of the samples whose cell cans were made of Sn-added ferritic stainless steel had not rusted yet in 100 days at room temperature, and also at temperature of 60° C. and relative humidity (RH) of 90%. Under extremely severe environmental conditions at temperature of 80° C. and relative humidity (RH) of 90%, one of the ten samples eventually rusted. This confirmed that a sealed battery whose cell can is made of Sn-added ferritic stainless steel has extremely excellent corrosion resistance. Since Sn-added ferritic stainless steel does not contain Ni, inexpensive sealed batteries can be realized.

(19) Sealing Performance

(20) As for sealed batteries according to the above embodiment, the sealing performance of laser welding is evaluated. For the evaluation, the following samples were prepared in order to confirm an advantage of sealing by laser welding: a sealed battery whose cell can opening is sealed by crimping; and a sealed battery whose cell can opening is sealed by laser welding in the same way as the sealed battery 1 shown in FIG. 1. FIG. 2 shows a sealed battery 1b sealed by crimping. In FIG. 2, the part relating to the sealing structure of a cell can 102 is enlarged. As shown in FIG. 2, a sealing part 110 includes: a terminal plate (in this embodiment, a positive terminal plate) 107; a sealing plate 106; and a gasket 109. The positive terminal plate 107 is made of metal. If the side toward the opening of the cell can 102 is defined as “up”, the positive terminal plate 107 has a saucer-like shape and the bottom of plate 107 is located upside. And, the positive terminal plate 107 includes a flange 111 formed on its edge. Below the positive terminal plate 107, the sealing plate 106, which is a metal disk, is placed. Procedures for sealing the cell can 102 by crimping will be described below.

(21) On the opening side of the cell can 102, a beading section 113 is formed. The gasket 109 which has not been sealed yet is in circular cup shape whose opening is located upside, and the gasket 109 has a hole 114 on its bottom which a positive lead tab 11 passes through. The positive electrode lead tab 11 is brought out of the winding structure accommodated in the cell can 102, and the lead tab 11 is welded to the lower surface of the sealing plate 106. Then, into the cell can 102, non-aqueous electrolyte solution is introduced. Subsequently, the resin gasket 109 is inserted inside the opening of the cell can 102, and the gasket 109 is arranged onto the foregoing beading section 113. Inside the gasket 109 attached to the inside of the cell can 102 in the foregoing manner, the sealing plate 106 and the positive terminal plate 107 are stacked. The opening of the cell can 102 is caulked inwards. The sealing part 110 is thereby fitted to the opening end of the cell can 102 and the cell can 102 is sealed.

(22) Next, for comparing the hermeticity of the batteries having different sealing structures, the sealed batteries 1 shown in FIG. 1 and the sealed batteries 1b shown in FIG. 2 were prepared as samples. Hermeticity test was conducted in which the samples were left under environmental conditions at temperature of 80° C. and relative humidity (RH) of 90%, and the relation between the number of storage days and the change in mass was observed. All samples have the same configuration and structure except for the sealing structure. The cell cans 2 and 102 were made of Ni-plated steel.

(23) Table 2 shows the result of the hermeticity test.

(24) TABLE-US-00002 TABLE 2 Change in Mass Test Sealing 10 days 30 days 60 days 100 days 80° C. Crimping −0.005 g −0.011 g −0.018 g −0.030 g 90% RH Laser −0.004 g −0.008 g −0.014 g −0.021 g welding

(25) As shown in Table 2, the masses of the samples gradually decreased as storage days increased. This confirmed that change in the masses of the samples sealed by laser welding is small compared to the samples sealed by crimping. That is, this confirms that the sealing structure by laser welding is superior in hermeticity to the sealing structure by crimping. For evaluating the sealing performance of the foregoing embodiment, the sealed batteries 1 which have the configuration shown in FIG. 1 and whose cell cans 2 are made of different material were made as samples. Specifically, the following two types of samples were prepared: samples in which the cell can 2 made of Sn-added ferritic stainless steel is sealed by laser welding with the sealing plate 6 made of Ni-plated steel; and samples in which the cell can 2 made of Ni-plated steel is sealed by laser welding with the sealing plate 6 made of Ni-plated steel.

(26) FIG. 3 is a schematic diagram showing how to evaluate sealing performance depending on the material of the cell can 2, and is an enlarged view of the rectangular area 60 indicated by a dashed line in FIG. 1. As shown in FIG. 3, the relationship between the weld-joint penetration d and the weld-joint speed V were examined: the weld-joint penetration d is the vertical width of an area, within a contact area 31 of the sealing plate 6 and the cell can 2, where the sealing plate 6 and the cell can 2 are joined by welding (hereinafter referred to as a weld-joint area 32); and the weld-joint speed is a speed of welding in which laser welding joint is performed until the weld-joint penetration d. Specifically, as for the samples (hereinafter referred to as a comparative example) whose cell cans 2 made of Ni-plated steel were sealed by laser welding joint, which were used for the foregoing hermeticity evaluation, the weld penetration d of the comparative example is defined as a relative value of 100. In the comparative example, the reciprocal of the time until the weld penetration d becomes 100 is defined as welding speed V of 100 (relative value). That is, in the comparative example, when welding speed V=100, the weld penetration d=100. The weld penetration d can be an indicator of weld strength, and the welding speed can be an indicator of length of processing time relating to laser welding. The relation between the welding speed V and the weld penetration d of the cell can 2 made of Sn-added ferritic stainless steel which is sealed by laser welding were examined.

(27) Table 3 shows the evaluation result of the sealing performance of the embodiment. FIG. 4 shows a graph of the result.

(28) TABLE-US-00003 TABLE 3 Relative value (Ni-plated steel: 100) Welding speed V 100 104 106 108 112 116 Weld penetration d 108 104 100 96 91 80

(29) As shown in Table 3 and FIG. 4, in the sealed battery 1 according to the embodiment, the weld penetration d=108 if the welding speed V=100. It was found that greater weld strength can be achieved in the same welding time. In other words, the weld penetration d can become 100 in a shorter period than in the comparative example. That is, the sealed battery 1 according to the embodiment, low-power laser beam in the laser welding process can achieve practical weld strength in the same processing time as in a conventional manner. Also, laser beam whose power is the same as in a conventional manner can achieve practical weld strength in shorter time. This makes it possible to reduce the cost for the laser welding process, and, as a result thereof, the sealed battery 1 can be more inexpensive. It goes without saying that making the sealing plate 6 of Sn-added ferritic stainless steel can further increase the welding speed.

(30) Other Embodiments

(31) As a sealed battery of the embodiment according to the present invention, a spiral-wound primary lithium battery having a cylindrical cell can is provided. However, a battery whose cell can is in a prismatic or polyhedral shape or the like may be employed as a sealed battery of the embodiment according to the present invention. Of course, the sealed battery is not limited to a lithium primary battery. A sealed battery may be an alkaline dry battery, a manganese dry battery or the like, and may also be a secondary battery. It is sufficient that a battery includes the following cell can: the cell can has a bottom and is in a cylindrical or prismatic or polyhedral shape; the cell can also serves as a collector of one of the electrodes; the cell can is made of Sn-added ferritic stainless steel; and the opening of the cell can is sealed.