KR20150113892A - Method of forming a prismatic battery case - Google Patents

Abstract

An object of the present invention is to provide a forming method which can efficiently forms an aluminum alloy plate to a prismatic battery case having good precision and high flatness. The method forms an aluminum alloy plate by a drawing process to a first angle cylinder (2) which is partially formed over around a side wall unit (2a) of slope wall surface (2f) at the same time and continuously performs a redrawing process or a finishing process while remaining a bottom unit (2d) of the first angle cylinder (2) as a bottom unit of the prismatic battery case. A plate thickness of the side wall is formed to final prismatic battery case having a 60% or lower thickness of the aluminum alloy plate.

Description

[0001] METHOD OF FORMING A PRISMATIC BATTERY CASE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a molding method of a prismatic battery case, which is a case of a Li-ion battery or the like.

BACKGROUND ART [0002] Lithium ion secondary batteries (Li-ion batteries) are widely used as power sources for portable telephones, note-type personal computers, electric vehicles and hybrid vehicles. In many cases, a plate material constituting such a Li-ion battery case (hereinafter also simply referred to as a battery case) includes a metal including its cover, and an iron alloy such as stainless steel or an aluminum alloy is used. Particularly, when a lid, a main body (can) of a battery case, or the like is formed of a molded product of an aluminum alloy plate (cold rolled plate) material by press molding, it is advantageous in terms of corrosion resistance, light weight, workability and cost.

The shape of these battery cases is a battery case having a square shape in transverse sectional shape, which has high mounting efficiency and excellent heat radiation performance, and has a flatness, that is, a ratio of a width of a wide side to a width of a narrow side Is significantly smaller), a flat battery case is widely used. Such a prismatic battery using a thin rectangular battery case is suitable for thinning and weight-saving of the device and also has a high spatial effect, so that it is important.

As a method of forming a prismatic battery case (battery can) having a high level of flatness, a transfer drawing method is known in which a metal plate such as an aluminum alloy is used as a molding material and a deep drawing by a transfer press machine ) And ironing are repeated 10 to 20 times to obtain a molded shape. However, in this molding method, a large number of expensive molds are required for multiple processes, an increase in facility cost due to a large transfer press, and processing due to a large press, the press speed can not be increased, There was a problem of.

Therefore, conventionally, various proposals have been made in order to solve the problems associated with the molding of the prismatic battery case.

For example, in Patent Document 1, a cold-rolled steel sheet containing 0.1% or less of carbon is deep-drawn as a battery can material punched into a predetermined shape to form a first angular cylinder having a substantially elliptical cross section, , And a DI-process in which a drawing process and an ironing process are consecutively performed all at once to mold a prismatic battery case.

However, in the method using the DI molding method in which the conventional drawing and ironing are continuously performed, such as Patent Document 1, the aluminum alloy sheet is subjected to molding after securing the plate thickness and shape accuracy to the rectangular cell case with high flatness it's difficult. This is because an aluminum alloy plate which is soft and has a low elastic modulus with respect to an iron alloy or steel such as SUS having high rigidity has greatly different behavior and characteristics in molding.

On the other hand, in Patent Document 2 and Non-Patent Document 1, a taper is provided on the upper edge of the container by the first drawing process (initial drawing), or a preliminary bottom surface portion having an outer diameter smaller than that of the product bottom surface portion, A preliminary inclined sidewall portion that is obliquely erected from the substrate is formed to obtain an intermediate (preliminary) shaped body. By re-drawing this, the bending angle by the die face of the side wall of the intermediate formed body is made smaller than 90 degrees by the presence of the taper or the preliminary inclined sidewall portion, and the flow of the material such as friction, It is proposed to reduce the resistance of the semiconductor wafer and then perform the redrawing process.

Japanese Patent No. 4119612 Japanese Patent No. 4325515

Plastic Machining 2, W. Johnson, P.B. Muller, October 30, 1965 Bai Houkan, "Reduced Processing of Containers with 1/10 Bottom", pp. 26-27

However, when the aluminum alloy plate is molded into a prismatic battery case having a high degree of flatness by a DI molding method in which drawing and ironing are continuously performed by the molding methods of Patent Document 2 and Non-Patent Document 1, It is also difficult to secure the shape accuracy.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a molding method capable of forming an aluminum alloy plate into a prismatic battery case with high flatness with good precision and efficiency.

To achieve the above object, a gist of a molding method of a prismatic battery case of the present invention is that,

And an inclined wall surface having a diameter reduced toward the bottom portion is formed partly around the periphery of the side wall portion, A first drawing machining step of forming a single rectangular box,

A slant wall surface formed by a redrawing process of the first crushing body and including a bottom portion and a side wall portion starting from the bottom portion peripheral portion and being reduced in diameter toward the bottom portion is formed partially around the periphery of the side wall portion, A second drawing processing step of forming a second square cylinder having a height higher than that of the first cylinder and a bottom portion of the first cylinder as the bottom portion,

And the sidewall portion has a height higher than that of the second angular cylinder and a thickness of the sidewall portion is larger than that of the aluminum alloy plate And 60% or less of the plate thickness, and further the bottom portion of the second cylinder is left as the bottom portion.

In the present invention, in the first drawing processing step, the inclined wall surface that is reduced in diameter toward the bottom forms a first angular cylinder formed partially around the circumference of the side wall portion. By the presence of the inclined wall surface, the bending angle of the sidewall of the first cylinder to be molded when the first cylinder is redrawn by the second drawing processing step is made smaller than 90 degrees.

As a result, when the first cylinder is redrawn, the deformation resistance due to the bending of the side wall portion is reduced. As a result, the drawing in the second step becomes smoother and the moldability can be improved, so that the thin metal sheet can be formed into a prismatic battery case having a flat bottom.

In addition to this, by performing the second drawing or finishing so that the bottom portion of the first cylinder is left as it is as the bottom portion of the prismatic battery case, the bottom portion of each of the first and second cylinders, The sidewall portions including the inclined wall surfaces of the first and second cylinders are mainly formed. Therefore, deformation resistance due to bending is further reduced as compared with the case where both bottom portions and side wall portions of the first and second cylinders are molded.

By forming these inclined wall surfaces and the bottom portion of the first angular cylinder as it is as the bottom portion of the angular cell case, the height of the second angular cylinder is higher than that of the second angular cylinder, and the final plate thickness of the side wall portion is set to be It is possible to efficiently form the aluminum alloy rectangular battery case with the precision reduced and the process cost reduced to 60% or less with a high accuracy and with a small number of process steps.

1 is a sectional view of a press apparatus showing an embodiment of a first drawing processing step of the present invention,
2 is a sectional view of a press apparatus showing an embodiment of a second drawing processing step of the present invention,
3 is a sectional view of a press apparatus showing an embodiment of a finishing process of the present invention,
Fig. 4 is a perspective view showing the blank blank 1 to be formed in Fig. 1,
Fig. 5 is a perspective view showing the first angular cylinder 2 formed in Fig. 1,
Fig. 6 is a perspective view showing a second flute 3 to be molded in Fig. 2,
Fig. 7 is a perspective view showing the final rectangular battery case 4 molded in Fig. 3; Fig.

Best Mode for Carrying Out the Invention Hereinafter, a preferred embodiment of the present invention, in which a material aluminum alloy plate is molded into a prismatic battery case, will be described in detail with reference to the drawings. In the present specification and drawings, constituent elements having substantially the same functional configuration are denoted by the same reference numerals, and redundant description will be omitted.

In the present invention, after the first drawing processing step shown in Fig. 1 and the second drawing processing step (redrawing processing) shown in Fig. 2 are performed, by the third finishing step shown in Fig. 3, Mold the case. The finishing process of Fig. 3 shows an example of the ironing process, and shows an aspect of molding the product square battery case shown in Fig. 7 by combining with the drawing process of Figs. 1 and 2 at the front end . Here, the terms first, second, and third in the process of the present invention merely indicate the order and distinction of the process, and the process is limited to only the first, second, and third processes, It does not mean that no other process enters between the three processes. That is, the range of adding or inserting the other processes such as the molding, the surface treatment and the like is suitably added between the first, second and third steps or between the first, second and third steps.

The first drawing processing step

In the first drawing process of Fig. 1, the material aluminum alloy plate 1 shown in Fig. 4 is divided into a first rectangular punch (punch) 10 shown in Fig. 1, a first rectangular die 11). Then, as shown in Fig. 5, it is formed into a square first cylinder 2 in a plan view.

To this end, a material aluminum alloy plate (material blank) 1 previously punched in a predetermined shape such as a circle, a square, or an ellipse (see FIG. 4) in plan view is attached to a press apparatus shown in FIG. do.

After the peripheral portion 1b of the material aluminum alloy plate 1 is sandwiched and pressed by the blank holder 12 and the first die 11, the first rectangular punch 10 is moved down The first punch 10 and the first die 11 cooperate to raise the first square die 11 so that the material aluminum alloy plate 1 is brought into contact with the first square cylinders 2 ).

Here, the first punch 10 and the first prismatic die 11 of Fig. 1 are formed so as to have a rectangular shape (rectangular shape) corresponding to or similar to the prismatic first cylinder 2, Sectional shape). The first rectangular punch 10 is partially formed with an inclined wall surface (tapered surface) 10a which is reduced in diameter toward the tip end 10b thereof.

As a result, the bottom portion 2d having a square shape as viewed in plan view and the four side wall portions 2a, 2a, 2b (starting from the periphery of the bottom portion 2d) shown in the sectional view of FIG. 1 or the perspective view of FIG. 2b and 2g and four sloped wall faces 2f, 2f, 2g and 2g which are diametrically reduced toward the bottom 2d are formed partially around the periphery of the side wall portions 2a, 2a, 2b and 2b So that the first cylinder (2) is formed. In the first column 2 of Fig. 5, reference numerals 2a and 2a denote opposing two sidewall portions on the side of the long side which are large and wide, and reference numerals 2b and 2b, A reference numeral 2e denotes a flat product extending outwardly from the peripheral edge of each of the side walls 2a and 2b; The outer flange.

(Inclined wall surface)

As described above, the first rectangular punch 10 is partially formed with inclined wall surfaces (tapered surfaces) 10a which are reduced in diameter so as to have a smaller diameter toward the tip 10b side. The oblique wall faces 2f and 2f are formed on the two sidewall portions 2a and 2a on the side of the wide side of the first corrugated body 2 by the inclined wall face 10a, The inclined wall faces 2g and 2g are formed on the narrow side wall portions 2b and 2b, respectively, as shown in Fig.

As a result, the first cylinder 2 is provided with the bottom portion 2d and the four side walls 2a, 2a, 2b, 2b and the four side walls 2a, 2a, 2b, The inclined wall faces 2f, 2f, 2g, and 2g are formed around the circumference (total length or entire width). Here, the inclined wall faces 2f and 2f are respectively present over the width (length) of the two side wall portions 2a and 2a on the side of the wide side and the inclined wall faces 2g and 2g are two (Length) of the side wall portions 2b and 2b, respectively.

These inclined wall faces 2f, 2f, 2g and 2g are formed by the side wall portions 2a, 2a, 2b and 2b from the respective side wall portions 2a, 2a, 2b and 2b toward the bottom portion 2d The long side and the short side of the substantially rectangular cross section are sequentially narrowed so that the gap between the inclined wall faces 2f and 2f and between the inclined wall faces 2g and 2g gradually narrows to be the long side and the short side of the bottom portion 2d It has a sloping wall.

The inclined wall faces 2f, 2f, 2g, and 2g are inclined to the inclined wall faces 2f, 2f, 2g, and 2g of the first angular cylinder 2 when they are formed in the second drawing processing step, Is set to be smaller than 90 degrees. As shown in Fig. 2, the inclined wall faces 2f, 2f, 2g, and 2g are formed so that, when redecorating (shaping) the first flats 2, The bending angles R (R shown in Fig. 2) of the wall surfaces 3f, 3f, 3g, and 3g can be made smaller than 90 degrees. Therefore, deformation resistance due to bending of the side wall portions 3a, 3a, 3b, and 3b including the inclined wall surfaces 3f, 3f, 3g, and 3g of the second cylinder is reduced. As a result, redrawing can be made more smoothly and moldability can be enhanced, so that a thin metal sheet can be formed into a prismatic battery case having a flat bottom. Here, the bend angles R of the inclined wall faces 3f, 3f, 3g, and 3g of the second square cylinder 2 mean that the respective side walls 3f, 3f, 3g, and 3g shown in FIG. (R).

The shape conditions such as the inclination or the height of the inclined wall faces 2f, 2f, 2g, and 2g in the first corner cylinder 2 are set so that the first 2f, 2g, 2g of the respective cylinders 2 can be made smaller than 90 degrees.

In this first drawing processing step, the thickness is the same as or larger than that of the original material aluminum alloy plate 1, and the first angular cylinder 2 having a rectangular cross-sectional shape and a constant height (depth) .

(The bottom of the first cylinder)

The width and the length of the bottom portion 2d of the first shell 2 are set such that the long side and the short side of the bottom portion 2d are spaced apart from each other by the first and second sides 2b, The cross section of the bottom section 2d is smaller than the cross section of the first angular cylinder 2, and the cross section of the bottom section 2d is smaller than that of the first cross section.

On the premise of this, in the present invention, the bottom portion 2d of the first flute 2 molded in the drawing step of the first step is placed on the bottom of the final rectangular cell case 4 shown in Fig. 7 The bottom portion 4d, or the bottom portion 4d.

For this purpose, the bottom portion 2d is formed so as to have a size or shape suitable for the bottom portion 4d of the rectangular battery case 4, which is the same as or slightly larger than the bottom portion 4d. The bottom portion 3d of the second flute 3 and the bottom portion 4d of the rectangular cell case 4 are formed by leaving the bottom portion 2d of the first flute 2 as is or as far as possible. A second drawing process and a finishing process, which will be described later, are performed.

The bottom part 2d of the first square cylinder 2 is left as it is or as much as possible to become the bottom part 4d of the end square battery case 4 because the bottom part 2d itself And the bottom portion 3d of the second corner cylinder 3 has the same or larger than or equal to a certain ratio of the bottom portion 2d and remains substantially unformed by redrawing or finishing. And the bottom portion 4d of the prismatic type battery case 4 as shown in Fig. However, it is acceptable that the bottom portion 2d is subjected to some molding in redrawing and finishing, and the size and shape thereof are partially or partially changed at the periphery of the bottom portion. The criterion for leaving the bottom portion 2d of the first angular cylinder 2 as it is or as much as possible and forming the bottom portion 4d of the prismatic battery case 4 is a rectangular cell case 4 (Long side x short side) of the bottom portion of the first flute 2 is in the range of 70% to 100% of the area (long side x short side) of the bottom portion 2d of the first flute 2 in Fig.

In Patent Document 2 and Non-Patent Document 1, it is also possible to provide a taper in the upper portion of the container by the first drawing process (initial drawing), or a preliminary bottom portion having an outer diameter smaller than that of the product bottom portion, A preliminary inclined sidewall portion is formed to obtain an intermediate (preliminary) formed body. However, the bottom portion of the intermediate (preliminary) formed article is not left as it is as a bottom portion of the product shape as in the present invention, but is molded together with the side wall. In other words, the area (long side x short side) of the bottom portion of the rectangular battery case 4 in Fig. 7 is necessarily smaller than 70% of the area (long side x short side) of the bottom portion 2d of the first shell 2 (Non-Patent Document 1), and conversely, it exceeds 100%, which inevitably becomes large (Patent Document 2). For this reason, the resistance against the flow of the material at the time of molding becomes larger in comparison with the present invention in which the bottom portion is formed as a bottom portion and the side wall is formed as a side wall sequentially.

1 and 5, the bottom 2d and the inclined wall 2f, 2f, 2g, 2g, 2g, and 2g are formed in the shape of the first cylinder 2 after the first drawing process, Is formed on the side of the bottom portion 2d of the first shell 2. In this case, As a result, the material on the side of the bottom portion 2d is subjected to extrusion molding during the first drawing process, resulting in thinning. Therefore, even in the finally obtained prismatic battery case shown in Fig. 7, the thickness of the bottom portion becomes thin, and the material flows toward the side wall, so that the shape of the deep prismatic battery case is obtained with a smaller amount of material usage. Therefore, the effect of reducing the amount of material used for the battery can is also obtained. Further, in the case of the present invention, since the bending angle at the shoulder of the die in the redrawing process to be described later is small, the vertical wall portion of the finally obtained rectangular cell case (battery can) Surface unevenness caused by the bending deformation occurring in the battery case is reduced, and a battery case with higher strength is obtained.

This first drawing processing step may be performed in one step or in plural steps or in multiple steps, and a normal press apparatus can be used. The drawing speed can be set in the range of 1 to 60 m / SPM and the blank holder load in the range of 0.5 kN to 500 kN under the conditions in a conventional press apparatus or drawing. In addition to the first drawing machining step, the second drawing machining step and the finishing step, various commercially available lubricants or lubricants may be used as required, as in a conventional press apparatus or drawing.

The second drawing processing step

Next, in the redrawing step of the second drawing process shown in Fig. 2, the formed first flats 2 shown in Fig. 5 are divided into the second rectangular punch 13 and the second rectangular punch 13, as shown in Fig. 2 The second square die (14) performs redrawing on the second square cylinder (3) having a further rectangular cross section. That is, the second angular punch 13 and the second angular die 14, which are partially formed on the inclined wall surface which is reduced in diameter toward the tip end, are formed in the second angular cylinder 3 shown in Fig. 5 Redraw processing.

Here, the second punch 13 and the second rectangular die 14 in Fig. 2 are formed in a shape corresponding to or similar to the rectangular second cylinder 3 in a plan view, Sectional shape). The second rectangular punch 13 is provided with an inclined wall surface (tapered surface) 13a which is reduced in diameter toward the tip end 13b thereof in the same manner as the rectangular shape 10 shown in Fig. 1, . The second square dice 14 is partially formed with an inclined wall surface (tapered surface) 14a whose diameter is reduced toward the lower side thereof.

Each of the side wall portions 2a and 2a including the inclined wall surface (inclined wall) 2f and 2f of the first angular cylinder 2 is divided by the inclined wall surface 13a into a wide width of the second angular cylinder 3 (Sloped walls) 3f and 3f, respectively, as shown in Fig. Each of the side wall portions 2b and 2b including the inclined wall surfaces 2g and 2g of the first crushing body 2 is divided into two narrow side walls 2b and 2b, (Inclined walls) 3g and 3g, respectively.

As a result, a bottom portion 3d and side wall portions 3a, 3a, 3b and 3b starting from the periphery of the bottom portion 3d as shown in Fig. 6, The height of the side wall portions 3a, 3a, 3b, 3b is higher than that of the first angular cylinder 2, and the inclined wall faces 3f, 3f, 3g, 3g are partially formed over the periphery of the side wall portion 4, It is possible to form the second corrugated body 3 having the bottom portion 2d of the first angular cylinder as its bottom portion 3d.

When the angular punch 13 such as the inclined wall 13a at the tip end is formed in a cross-sectional shape similar to that of the first angular cylinder, when the first angular cylinder 2 is redrawn, The oblique wall face 13a at the tip of the square punch 13 and the oblique wall faces 2f, 2f, 2g, 2g of the first angular cylinder correspond to each other. The bending angle R of the sidewall portions 2a, 2a, 2b, and 2b and the inclined wall surfaces 2f, 2f, 2g, and 2g of the first square cylinder 2 at the time of molding is 90 It can be made smaller than it is. Here, the bending angle R is the reference numeral R shown in Fig. 2, and the tapered portion 14a provided in the die 14 to the bifurcated long side of the molded second cylinder 3 Is an angle formed by the side wall portions 3a, 3a and the vertical direction.

As described above, the bottom portion 2d of the first angular cylinder 2 molded in the drawing process of the first step is left as it is or as far as possible, As the bottom 4d of the base 4. That is to say, the bottom portion 2d of the first shell 2 can be made to be the same size or shape as the bottom portion 4d of the final rectangular cell case 4, The first cylinder 2 is formed. That is, the area (long side x short side) of the bottom portion 4d of the rectangular battery case 4 in Fig. 7 is smaller than the area (long side x short side) of the bottom portion 2d of the first square cylinder 2 % To 100%.

As a result, the bottom portion 2d of the first angled cylinder 2 is formed as the bottom portion 3d of the second angled cylinder 3 and the side wall portions 2a, 2a, 2b of the first angled cylinder 2 3b and 3b and the inclined wall surfaces 3f, 3f, 3g and 3g of the second columnar body 3 and the slanting wall surfaces 2f, 2f, 2g and 2g, The resistance against the flow of the material at the time of molding becomes smaller. This same effect can be obtained also in a finishing step to be described later.

In the redrawing step of Fig. 2, more specifically, as shown in Fig. 2, the first flats 2 molded in the first drawing process of Fig. 1 are mounted on the press apparatus. At this time, it is preferable to insert the sleeve 15 into the space (gap) 18 between the first angular cylinder and the second angular punch 13 as shown in Fig. This is because the sleeve 15 is previously mounted on the outer peripheral side (outer surface side) of the second rectangular punch 13 and the sleeve 15 is fixed to the first angular punch 13 (Or the second dice 14 is moved upward) along the inner wall surface 2a of the base plate 2 (see Fig.

The sleeve 15 has an inside dimension and a cross-sectional shape corresponding to the outside dimension and the cross-sectional shape of the second rectangular punch 13, and has an inside dimension and a cross-sectional shape corresponding to the inside dimension of the first square cylinder 2 to be molded in this second redrawing step (Gap) that is not supported by the second rectangular punch.

Thereafter, the second rectangular punch 13 is lowered or the second rectangular die 14 is raised so that only the second rectangular punch 13 is advanced (entered) into the second rectangular die 14 as shown in Fig. 2 , And the second rectangular punch 13 and the second rectangular die 14 are further redrawn through the sleeve 15 in cooperation with each other. Then, the second flats 3 are formed as shown in Fig.

The second angular cylinder 3 is formed so that the ratio of the short side to the long side is smaller (flatter) than the transverse sectional shape of the first angular cylinder 2 and the height h1 of the first angular cylinder 2 (h2) having a high cross-sectional shape in the height direction. In the drawing process step shown in Fig. 2, the product outer flange 3e that extends outward as shown in Fig. 6 is left, but the product outer flange 3e is not left in the second angular cylinder 3 Drawing may be performed.

2 and 6, reference numerals 3a and 3a denote opposing two side walls on the side of the long side which are large and wide, and reference numerals 3b and 3b denote side walls on the side of the small and narrow side of the short side, Reference numeral 3e denotes a flat outer side of the product extending outward from the peripheral edge of each of the side walls 3a and 3b; It is a flange.

2, in the shape of the die 14 at the time of redrawing, the upper surface 15 of the second square dice 14 is formed on the outer surface of the first flute 2 before redrawing, 2f, 2g, and 2g. As a result, the material flowing during the redrawing moves along the upper surface 15, so that wrinkles do not occur, so that deformation is smoother and moldability is further improved.

(Use of sleeve)

In the present invention, it is preferable to use the sleeve 15 fitted over the second punch 13 in the second drawing processing step. In the second drawing machining step, when the first angular cylinder 2 is redrawn to form the second angular cylinder 3 having a taller (deeper) shape than the smaller rectangular cross-sectional shape, The two punches 13 have a rectangular cross-sectional shape that is smaller than the first cylinder 2. As a result, as shown in Fig. 2, there is inevitably a space (gap) not supported by the second punch 13 around each of the cylinders 2.

In the redrawing step without using the sleeve, when the forming force is applied from the metal mold 14 around the first flute 2 due to the presence of the space not supported by the second punch 13, The load portion of the forming force is buckled, and wrinkles tend to occur. For this reason, there is a possibility that the molding can not be formed due to irregular processing depending on the part, or the plate thickness and the shape precision can not be secured even if it can be molded. On the other hand, when making the second square cylinders 3 having a rectangular cross-sectional shape smaller in diameter and taller (deeper) than the first angular cylinder 2 having a rectangular transverse cross section, The space can be filled up. Therefore, even if a forming force is applied from the die (mold) 14 around the first flute 2, the load portion of the forming force in the first flute 2 is not buckled , Wrinkles do not occur. Therefore, it is possible to perform the uniform processing without depending on the part, so that the molding can be performed, and the plate thickness and the shape accuracy can be secured.

The sleeve 15 for embedding a space (gap) having such a rectangular cross-sectional shape needs to have an angular annular cross-sectional shape approximately or similar to such a space (gap) 18 as a matter of course. During the molding of the second redrawing process, the sleeve 15 is stopped at the insertion position at the initial stage of molding, so that only the second punch 13 advances into the second die 14 to perform molding . Depending on the type of the aluminum alloy to be molded, the material of the sleeve can be appropriately selected from materials of the same kind of aluminum alloy, rubber, resin, etc., in addition to steel for a mold.

As in the first drawing processing step, the second drawing processing step may be performed in a single step or a plurality of steps or in multiple steps, and a normal press apparatus can be used. The conditions for the drawing forming, the forming speed, and the blanking load, such as 1 to 60 punches per minute, and the blank holder load, such as 0.5 kN to 500 kN, Can be set in relation to the conditions of the process.

Third Finishing Process

After the above-described plural-step or multi-step drawing processing, the second cylinder 3 is subjected to a drawing process or an ironing process as a third process, or a combination of a drawing process and an ironing process Shaped battery case 4 shown in Fig. 7 in which the height of the sidewall portion of the sidewall portion is reduced to 60% or less of the thickness of the aluminum alloy plate .

3 is a view showing a state in which the second square cylinders 3 having a rectangular transverse cross section are divided into a third rectangular punch 16 and a third rectangular ironing die 17 In particular, the side wall 3a is ironed and thinned (reduced in thickness) to mold the final rectangular cell case 4 shown in Fig. Here, the third rectangular punch 16 and the third rectangular ironing die 17 in Fig. 3 correspond to the square type battery case 4, which is a square type when seen from the same plane as seen in Fig. 7 And has a similar rectangular shape (rectangular cross-sectional shape). With respect to such ironing, it is also possible to repeatedly perform machining a plurality of times so that the thickness of the side wall is gradually reduced.

The inclined wall faces 3f, 3f, 3g, and 3g of the second square cylinder 3 are all formed into the side walls 4a, 4a, 4b, and 4b of the rectangular cell case 4 at the time of ironing.

The bottom portion 3d of the second angular cylinder 3 formed in the redrawing process is formed so that the area (long side x short side) of the bottom portion 4d of the square type battery case 4 is larger than the area (4d) of the prismatic battery case (4) so as to be in the range of 70% to 100% of the area (long side x short side) of the bottom portion (2d) As a result, the bottom portion 3d of the second square cylinder 2 is formed as the bottom portion 4d of the rectangular cell case 4 and the side wall portions 3a, 3a, 3b, 3b and the inclined wall faces 3f, 3f, 3g and 3g are sequentially formed as the side walls 4a, 4a, 4b and 4b of the prismatic battery case 4 so that the resistance against the flow of the material at the time of molding Lt; / RTI >

The final rectangular cell case 4 has substantially the same ratio of the short side to the long side as compared with the rectangular cross sectional shape of the second square cylinder 3 and the height h2 of the second square cylinder 3, And the height h3 is higher or deeper than the height h3. Then, the final thickness of at least the sidewalls is reduced to 60% or less of the thickness of the material metal sheet by ironing. In the final rectangular cell case 4 of Fig. 7, reference numeral 4a denotes two opposing side walls on the side of the long side which are large and wide, two side walls which are opposed to each other on the small and narrow side, Reference numeral 4c denotes an opening above the hollow portion, and 4d denotes a bottom portion. Even in the step of the rectangular battery case 4 of Fig. 7, the product outer flange 4e is left widened outward. However, without leaving the product outer flange 4e, good. This product outer flange 4e is removed by a trimming process.

In the present invention, the drawing process shown in Figs. 1 and 2 is repeated to form the second flute 3 having a square cross-sectional shape. In the ironing process of Fig. 3, the above-mentioned sleeve is not used, The final rectangular cell case 4 is formed by performing ironing processing that does not change the cross-sectional shape but reduces only the plate thickness (thickness). Therefore, it is possible to perform stable molding with excellent shape and thickness accuracy without causing occurrence of molding defects such as wrinkles, as in the conventional combination of drawing and ironing.

The ironing process as the finish machining process can use not only the one stage shown in Fig. 3 but also a press apparatus, conditions, and lubricant that perform multi-stage ironing.

Square type battery case

The final rectangular battery case 4 shown in Fig. 7 has a rectangular thin flat cross-sectional shape having a rectangular cross-sectional shape and a short-side / long-side ratio of approximately the same as those of the second rectangular shell 3, (Tall or deep) shape having a height (h3) higher than a height (h2) The plate thickness (thickness) is a thin thickness in which the final plate thickness of the two iron-worked side walls 4a and 4b is reduced to 60% or less of the plate thickness of the material metal plate.

The final plate thickness of the side wall 3a is set such that the length (width) or height h3 of the side wall 4a at the long side, the side wall 4c at the short side, the ratio of the short side / long side, And the like. In this respect, according to specifications of a typical Li-ion secondary battery or the like, the plate thickness of the side wall 4a of the prismatic battery case 4 is selected from the range of 0.3 mm to 2 mm. When the thickness of the side wall 4a is less than 0.3 mm, there is a possibility that the required rigidity and strength are insufficient depending on the strength of the material metal plate. On the other hand, if the thickness of the side wall 4a exceeds 2 mm, the weight becomes heavy, and it becomes difficult to perform good precision in the thin groove, the groove for breaking the safety valve, and the like. The final plate thickness of the bottom portion 4d may be the same as or different from that of the material metal plate shown in Fig. 1, depending on the required characteristics of the prismatic battery case 4, May be made thinner than other plates.

Although not shown in the figure, the rectangular battery case 4 is equipped with a sealing lid including a normal external positive electrode, an electrolyte inlet, a cover, and other required components such as a safety valve, as a Li-ion battery case .

Material Aluminum alloy plate

When the material aluminum alloy sheet used in the present invention is reduced to 60% or less of the sheet thickness of the material sheet by both drawing and ironing, the side wall 4a is in the range of 0.3 mm to 2 mm It shall be assumed that the plate thickness is equal to the plate thickness. Thinning of the battery case 4 is an important factor for increasing the capacity of the battery. However, the battery case 4 can maintain the necessary pressure resistance even by the thinning of the battery case 4, It is necessary to make it possible to perform both machining. For this reason, the material aluminum alloy sheet is required to have excellent moldability in a rectangular prismatic battery case when drawing and ironing are combined, and is excellent in corrosion resistance and high in strength and rigidity even when thinned. In view of these points and weight reduction, an aluminum alloy plate is preferable.

The material strength of the material aluminum alloy sheet is preferably set in the range of 30 MPa to 180 MPa at an O.2% proof strength after tempering such as solution treatment, quenching treatment, age hardening treatment, cold rolling and annealing. As the aluminum alloy satisfying these requirements, 3000 (AI-Mn) based aluminum alloys standardized in J1S to AA are preferred, and A3003 aluminum alloys are preferred. Among them, 1000-based aluminum alloys standardized to J1S to AA, When sealed, a pure aluminum alloy, A1050 alloy, is preferred. These alloys are also preferable in terms of corrosion resistance. However, depending on the use conditions and molding conditions, alloys having improved creep resistance (creep deformation resistance) and the like of these alloys or 5000-series or 6000-series aluminum alloys having a higher strength than these alloys may be used.

[Industrial applicability]

SUMMARY OF THE INVENTION The present invention provides a molding method capable of forming an aluminum alloy plate into a prismatic battery case having high accuracy and efficiency and having a high flatness. Therefore, it can be suitably used in a manufacturing process of a prismatic battery case for a lithium ion secondary battery.

1: material metal plate 2: first cylinder
2a, 2b: side wall 2d: bottom part
2f, 2g: inclined wall surface 3: second cylinder
2a, 2b: side wall 3d: bottom part
3f, 3g: inclined wall surface 4: square type battery case
4a, 4b: side wall 4d: bottom part
10: a first prismatic punch 11: a first prismatic die
12: Blank holder 13: Secondary punch
14: a square dice, 15: a sleeve
16: triangular punch 17: triangular ironing die

Claims (3)

And an inclined wall surface which is formed by a drawing process and has a bottom portion and a side wall portion starting from the periphery of the bottom portion and which is reduced in diameter toward the bottom portion is partially formed over the periphery of the side wall portion, A first drawing processing step of carrying out a first drawing process,
Wherein the first cylinder is redrawn to form a bottom portion and a side wall portion starting from the bottom portion and an inclined wall surface that is reduced in diameter toward the bottom portion is formed partially around the periphery of the side wall portion, A second drawing processing step of forming a second square cylinder having a height higher than that of the first cylinder and a bottom portion of the first cylinder as the bottom portion,
And the sidewall portion has a height higher than that of the second angular cylinder and the thickness of the sidewall portion is larger than that of the aluminum alloy plate And a finishing step of forming the battery into a rectangular battery case which is not more than 60% of the plate thickness and further the bottom portion of the second cylinder is left as the bottom portion
Molding method of prismatic battery case. The method according to claim 1,
In the first drawing processing step, the workpiece aluminum alloy plate is drawn by the first angular punch and the first prismatic die partially formed on the inclined wall surface which is reduced in diameter toward the tip side,
Wherein the second drawing processing step includes a step of forming a second rectangular punch partially forming an inclined wall surface which is reduced in diameter toward the tip side by four circumferences and a step of forming a slanted wall surface corresponding to the inclined wall surface of the second angular cylinder The first angular cylinder is redrawn by a biaxial dice,
Characterized in that the finishing step is carried out by ironing
Molding method of prismatic battery case. 3. The method according to claim 1 or 2,
And the area of the bottom of the prismatic battery case is in a range of 70% to 100% of the area of the bottom of the first cylinder.
Molding method of prismatic battery case.

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