Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
  • B21D—WORKING OR PROCESSING OF SHEET METAL OR METAL TUBES, RODS OR PROFILES WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
  • B21D22/00—Shaping without cutting, by stamping, spinning, or deep-drawing
  • B21D22/20—Deep-drawing
  • B21D22/30—Deep-drawing to finish articles formed by deep-drawing
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
  • B21D—WORKING OR PROCESSING OF SHEET METAL OR METAL TUBES, RODS OR PROFILES WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
  • B21D51/00—Making hollow objects
  • B21D51/16—Making hollow objects characterised by the use of the objects
  • B21D51/26—Making hollow objects characterised by the use of the objects cans or tins; Closing same in a permanent manner
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B21—MECHANICAL METAL-WORKING WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
  • B21D—WORKING OR PROCESSING OF SHEET METAL OR METAL TUBES, RODS OR PROFILES WITHOUT ESSENTIALLY REMOVING MATERIAL; PUNCHING METAL
  • B21D22/00—Shaping without cutting, by stamping, spinning, or deep-drawing
  • B21D22/20—Deep-drawing
  • B21D22/28—Deep-drawing of cylindrical articles using consecutive dies
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
  • B65D—CONTAINERS FOR STORAGE OR TRANSPORT OF ARTICLES OR MATERIALS, e.g. BAGS, BARRELS, BOTTLES, BOXES, CANS, CARTONS, CRATES, DRUMS, JARS, TANKS, HOPPERS, FORWARDING CONTAINERS; ACCESSORIES, CLOSURES, OR FITTINGS THEREFOR; PACKAGING ELEMENTS; PACKAGES
  • B65D1/00—Rigid or semi-rigid containers having bodies formed in one piece, e.g. by casting metallic material, by moulding plastics, by blowing vitreous material, by throwing ceramic material, by moulding pulped fibrous material or by deep-drawing operations performed on sheet material
  • B65D1/12—Cans, casks, barrels, or drums
  • B65D1/14—Cans, casks, barrels, or drums characterised by shape
  • B65D1/16—Cans, casks, barrels, or drums characterised by shape of curved cross-section, e.g. cylindrical
  • B65D1/165—Cylindrical cans
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B65—CONVEYING; PACKING; STORING; HANDLING THIN OR FILAMENTARY MATERIAL
  • B65D—CONTAINERS FOR STORAGE OR TRANSPORT OF ARTICLES OR MATERIALS, e.g. BAGS, BARRELS, BOTTLES, BOXES, CANS, CARTONS, CRATES, DRUMS, JARS, TANKS, HOPPERS, FORWARDING CONTAINERS; ACCESSORIES, CLOSURES, OR FITTINGS THEREFOR; PACKAGING ELEMENTS; PACKAGES
  • B65D1/00—Rigid or semi-rigid containers having bodies formed in one piece, e.g. by casting metallic material, by moulding plastics, by blowing vitreous material, by throwing ceramic material, by moulding pulped fibrous material or by deep-drawing operations performed on sheet material
  • B65D1/40—Details of walls
  • B65D1/42—Reinforcing or strengthening parts or members
  • B65D1/46—Local reinforcements, e.g. adjacent closures

Definitions

• This invention relates to a two-piece metal can in which a trunk section and a bottom section are formed integrally using an aluminum or aluminum alloy sheet material and a manufacturing method thereof, and more specifically, to a manufacturing method for shaping the bottom section into a desired shape or structure.
• a structure of the bottom section of the metal can of this kind is disclosed in the publication of Japanese Patent No. 6448217 .
• the can described in the publication of Japanese Patent No. 6448217 has been developed for the purpose of improving the strength of a bottom section, and in the can described therein, a dome part having a specific configuration is formed inside of an annular grounding part.
• a counter part is continuously formed on the inner periphery of the annular grounding part, and the dome part is formed on the counter part to protrude upwardly (toward the inner side of the can, or depressed from the outer side of the can).
• the grounding part is an annular section having an arcuate cross-section protruding downwardly.
• the counter part is a so-called inclined wall portion that is slightly inclined toward the center axis of the can.
• the dome part is a curved section formed in the inner peripheral side of the counter part, and smoothly curved toward the center of the can.
• a curvature radius of a central portion falls within a range from 55 mm to 62 mm
• a curvature radius of a portion extending radially outwardly from the central portion falls within a range from 33 mm to 37 mm.
• the central portion and the portion extending radially outwardly from the central portion are formed continuously without forming a sharp bend therebetween. For this reason, the curved section will not be subjected to a stress concentration so that the strength of the can against the load applied from an internal space of the can may be enhanced.
• the two curved portions (having arcuate cross-sections) of the dome part in the bottom of the can may be formed smoothly and continuously without forming a sharp bend therebetween by setting the curvature radii of the curved portions within the ranges described in Japanese Patent No. 6448217 . Consequently, the strength of the dome part may be enhanced, and a fragile portion as a starting point of so-called buckling may be eliminated.
• the inventors have found a fact that the strength of the dome part is affected not only by the local stress concentration but also by configurations of the dome part itself and a portion in the vicinity thereof, and also found an optimum configuration of the dome part for preventing an occurrence of the buckling.
• the dome part is deformed or buckled by a rise in an internal pressure or a large impact load applied thereto when the can is dropped to the ground. Consequently, the central portion of the dome part protruding upwardly is flattened and eventually inverted to protrude downwardly, or the portion of the dome part inside of the periphery thereof (as a boundary between the dome part and the counter part) is entirely reversed to protrude downwardly.
• a resistance against the load reversing the dome part to protrude downwardly may be increased thereby enhancing the strength of the dome part.
• an internal content of the can is reduced.
• an allowable height of the dome part is limited, but it is necessary to set the height of the dome part within the range of such limitation so as to ensure the strength.
• the dome part is shaped to have a cross-section in which a plurality of arcs are joined smoothly and continuously.
• those arcs have to be joined smoothly and continuously.
• curvature radii of the arcs are restricted, and in addition, the curvature radius of the respective arcs are preferably set taking account of the load applied thereto. Specifically, when the can is dropped, an impact load is applied to the central portion of the dome part substantially perpendicularly, and to the peripheral portion of the central portion obliquely. Therefore, the curvature radius of the arc in the central portion of the dome part is set greater than that of the arc in the peripheral portion.
• the dome part is protruded more significantly and the strength thereof is increased by reducing a diameter thereof or a diameter of the grounding part (or a rim part).
• a diameter of the grounding part in order to allow the can to erect stably, it is necessary to maintain a diameter of the grounding part to a somewhat large diameter. That is, it is necessary to form the dome part to protrude upwardly so as to ensure the strength while maintaining the diameter of the grounding part to a somewhat large diameter.
• the strength of the dome part is greatly affected by the diameter of the dome part or the grounding part.
• the curvature radii of the two arcuate surfaces forming the dome part are set to the specific values to eliminate a sharp bend at which the stress is concentrated.
• the curvature radii of the two arcuate surfaces are not set to those specific values without taking account of how the deformation load acts, and without taking account of other factors affecting the strength. Therefore, the metal can has to be improved to enhance the strength of the bottom of the metal can against deformation such as buckling of the dome part, in other words, to reduce a thickness while maintaining the deformation strength.
• the inventors have studied the factors affecting the strength of the metal can and developed the present invention.
• An object of the present invention is to provide a two-piece metal can in which the strength of a domed bottom section formed integrally with a trunk section is enhanced, and a method for manufacturing the two-piece metal can in such a manner as to reduce a thickness of the two-piece metal can so as to use the material efficiently.
• a two-piece metal can in which a cylindrical trunk section is formed integrally with a bottom section closing a lower end of the trunk section.
• the bottom section includes: a rim section whose diameter is smaller than a diameter of the trunk section, and which is shaped entirely into a circular shape protruding downwardly; a counter section extending upwardly from a lower end of the rim section toward an inner circumferential side to serve as an inner circumferential wall of the rim section; and a domed section formed continuously from an upper end of the counter section in which a top portion is formed at a central portion thereof.
• the domed section includes: a first arcuate portion that is formed around a center of the domed section whose cross-section is an arcuate cross-section having a predetermined first curvature radius; and a second arcuate portion that is formed between the first arcuate portion and the counter section while being joined smoothly to the first arcuate portion, and whose cross-section is an arcuate cross-section having a predetermined second curvature radius.
• a third arcuate portion may be formed between the second arcuate portion and the counter section while being joined smoothly to the second arcuate portion and the counter section.
• a cross-section of the third arcuate portion may also be an arcuate cross-section, and a third curvature radius of the third arcuate portion may be 1.5 mm or larger but 3.5 mm or smaller.
• a diameter of the rim section may be 46 mm or larger but 48 mm or smaller.
• a manufacturing method of a two-piece metal in which a bottom section is formed integrally with a trunk section by drawing and ironing a metal sheet.
• the bottom section includes: a rim section whose diameter is smaller than a diameter of the trunk section, and which is shaped entirely into a circular shape protruding downwardly; a counter section extending upwardly from a lower end of the rim section toward an inner circumferential side to serve as an inner circumferential wall of the rim section; and a domed section formed continuously from an upper end of the counter section in which a top portion is formed at a central portion thereof.
• the domed section includes a first arcuate portion that is formed around a center of the domed section whose cross-section is an arcuate cross-section having a predetermined first curvature radius; and a second arcuate portion that is formed between the first arcuate portion and the counter section while being joined smoothly to the first arcuate portion, and whose cross-section is an arcuate cross-section having a predetermined second curvature radius.
• the outer diameter of the domed section may correspond to an outer diameter of the doming punch.
• a third arcuate portion may be formed between the second arcuate portion and the counter section while being joined smoothly to the second arcuate portion and the counter section.
• a cross-section of the third arcuate portion may also be an arcuate cross-section, and a third curvature radius of the third arcuate portion may be 1.5 mm or larger but 3.5 mm or smaller.
• the rim section may be formed into an annular shape in which a diameter thereof is 46 mm or larger but 48 mm or smaller.
• the height Y of the domed section is determined based on an internal volume of the metal can, and the diameter DP of the domed section is determined based on the diameter of the rim section set to a value possible to allow the metal can to stand in a stable manner.
• the upper limit value and the lower limit value of the ratio between the first curvature radius and the second curvature radius is determined based on the height Y and the diameter DP of the domed section. Given that the above-mentioned ratio is set to the upper limit value, a strength of the domed section is enhanced to the maximum so that a maximum internal pressure not to cause a buckling of the domed section may be increased.
• a drop impact strength of the domed section may be enhanced to the maximum. That is, a height at which the domed section will not be buckled even if the metal can is dropped therefrom may be heightened to the maximum.
• the strength of the domed section decreases significantly given that the aforementioned ratio exceeds the upper limit value. That is, the upper limit value of the aforementioned ratio is a critical value to increase the strength of the domed section.
• the domed section is shaped such that the aforementioned ratio between the curvature radii is set to the upper limit value at which the strength of the domed section is enhanced to the maximum or falls within a predetermined range lower than the upper limit value. Therefore, a thickness of the metal can may be reduced without reducing or while maintaining the strength of the domed section. For this reason, it is possible to reduce the cost of the metal can, and the material of the metal can may be saved effectively.
• FIG. 1 and FIG. 2 An example of an intermediate product of a metal can 1 according to the present invention formed during a forming (manufacturing) process is schematically shown in FIG. 1 and FIG. 2 .
• the example shown therein is a two-piece can formed by drawing and ironing e.g., an aluminum sheet, in which a trunk section 2 and a bottom section 3 are formed integrally.
• the trunk section 2 has a simple cylindrical shape, and the bottom section 3 is formed integrally with a lower end portion of the trunk section 2.
• the lower end portion of the trunk section 2 is processed to gradually reduce a diameter thereof (i.e., shrunk) to form a rim section 4.
• the rim section 4 is also referred to as a ground section, and a portion in an inner circumferential side of the rim section 4 is subjected to the so-called doming process to be shaped into a domed section 5 that is curved to project toward an internal space of the trunk section 2 (i.e., upwardly in FIG. 1 ).
• the metal can 1 has a structure possible to withstand the internal pressure exerted e.g., by sparkling beverage held therein, and to withstand an impact load applied thereto when it is dropped or handled roughly.
• the rim section 4 serves as a contact surface or a contact ring of the metal can 1 being placed.
• an outer circumferential portion is shrunk and an inner circumferential portion is bent upwardly so that the rim section is shaped entirely into a circular shape protruding downwardly.
• a diameter D4 of the rim section 4 is set to 46 mm or larger but 48 mm or smaller.
• a tip (i.e., a lower end) of the rim section 4 is curved smoothly to project downwardly and to have a predetermined curvature radius.
• An inner circumferential wall of the rim section 4 serves as a counter section 6 that is a cylindrical wall erecting parallel to the central axis of the metal can 1, or a tapered wall in which a diameter of an upper portion thereof is slightly reduced.
• the domed section 5 is formed continuously from an upper end portion of the counter section 6, and the domed section 5 including a boundary with the counter section 6 is curved entirely to form a smooth curved surface (protruding upwardly).
• the domed section 5 is formed of a plurality of arcuate portions smoothly joined to one another.
• a first arcuate portion 5A is formed within a predetermined area around a center of the domed section 5, and a cross-section of the first arcuate portion 5A along the center axis is an arcuate cross-section having a predetermined curvature radius Ra.
• a second arcuate portion 5B is formed within a predetermined area on radially outer side of the first arcuate portion 5A, and a cross-section of the second arcuate portion 5B along the center axis of the metal can 1 is also an arcuate cross-section having a predetermined curvature radius Rb.
• a radial distance from the center axis to a boundary between the first arcuate portion 5A and the second arcuate portion 5B (that is, a radius r measured from the central axis) is about half of a radial distance from the center axis to a radially outer end of the second arcuate portion 5B.
• a position of the above-mentioned boundary varies according to the curvature radii R and Rb.
• the radially outer end of the second arcuate portion 5B comes close to an upper end of the counter section 6, and the second arcuate portion 5B is joined to the counter section 6 through a third arcuate portion 5C.
• the third arcuate portion 5C is formed between the radially outer end of the second arcuate portion 5B and the upper end of the counter section 6.
• the third arcuate portion 5C is formed to connect the second arcuate portion 5B smoothly to the counter section 6, and a curvature radius thereof (i.e., a curvature radius of an arcuate cross-section along the central axis) is set to e.g.,1.5 mm or larger but 3.5 mm or smaller.
• the arcuate portions 5A, 5B, 5C and the counter section 6 are "smoothly connected" to one another to have a common tangent line at each connection edge, or to reduce an angular difference between tangent lines at each connection edge as much as possible even if the tangent lines are not completely overlap each other.
• the central portion of the domed section 5 is a top portion 7 as a highest portion, and the first arcuate portion 5A extends within the above-mentioned radius r while being flattened gradually toward the top portion 7.
• the second arcuate portion 5B extends within a predetermined area of radially outer side of the first arcuate portion 5A, and an outer peripheral portion thereof is curved gradually downwardly. Therefore, when the metal can 1 filled with the content is dropped and an impact force is applied thereto, the first arcuate portion 5A is supported by the second arcuate portion 5B from below.
• the strength of the domed section 5 is governed not only by curvature radii of the arcuate portions 5A, 5B, and 5C, but also by a diameter and a height thereof.
• the diameter D4 of the rim section 4 which affects the standing stability of the metal can 1 is associated with the diameter of the domed section 5, and hence the diameter of the domed section 5 is restricted.
• the internal volume of the metal can 1 is associated with the height of the domed section 5, and hence the height of the domed section 5 is also restricted.
• the inventors of the present invention have intensively examined the preferred shape of the domed section 5 taking account of the way the load is applied to the domed section 5 to buckle the domed section 5, and the above-mentioned restrictions. Furthermore, the inventors of the present invention have also examined the effects of the arcuate portions 5A, 5B, and 5C, and a diameter DP and a height Y of the domed section 5 to the strength of the domed section 5. Details and results of the examination will be described hereinafter.
• test pieces individually having the shape shown in FIG. 1 were prepared. According to the manufacturing method of the present invention, each of the test pieces was formed by drawing and ironing a blank punched out of a metal sheet to shape the blank into a cup shape, and pressing the bottom section thereof by an after-mentioned doming punch to shape the bottom section into a predetermined shape. That is, the test pieces were formed by conventionally known procedures.
• the diameter D4 i.e., a grounding diameter
• a bottom depth DD was varied to 11.7 mm, 11.4 mm, 11.1 mm, and 10.8 mm.
• the bottom depth DD is a distance from the lower end of the rim section 4 (or the metal can 1) to the top portion 7 of the domed section 5.
• the doming punch 8 shown in FIG.
• the outer diameter DP corresponds to a diameter DP of the domed section 5.
• a substantial height Y of the domed section 5 corresponds to a height from the boundary between the second arcuate portion 5B and the third arcuate portion 5C to the top portion 7 of the domed section 5.
• the height Y of the domed section 5 was 6.95 mm.
• the height Y of the domed section 5 was 6.61 mm.
• the height Y of the domed section 5 was 6.26 mm.
• the height Y of the domed section 5 was 5.93 mm.
• the curvature radius Ra of the first arcuate portion 5A and the curvature radius Rb of the second arcuate portion 5B were varied to the extent that the arcuate portions 5A to 5C are joined smoothly to form a curved surface protruding upwardly.
• the examination was conducted to measure pressure resistance of each of the can bodies by pressurizing the liquid (i.e., water) held in the can bodies while fixing the rim section 4 from below and from radially outer side.
• the pressure resistance corresponds to a pressure at which the domed section was buckled. That is, the pressure resistance corresponds to the strength of the domed section.
• Measured values of the pressure resistance are indicated in a diagram shown in FIG. 3 .
• the horizontal axis represents a ratio (Ra/Rb) between the curvature radius Ra of the first arcuate portion 5A and a curvature radius Rb of the second arcuate portion 5B (hereinafter, also referred to as the curvature radius ratio)
• the vertical axis represents the pressure resistance (MPa) with respect to the curvature radius ratio
• the curve L1 represents measured values of the metal can 1 in which the bottom depth was 11.7 mm
• the curve L2 represents measured values of the metal can 1 in which the bottom depth was 11.4 mm
• the curve L3 represents measured values of the metal can 1 in which the bottom depth was 11.1 mm
• the curve L4 represents measured values of the metal can 1 in which the bottom depth was 10.8 mm.
• the pressure resistance increases with an increase in the aforementioned ratio, and the pressure resistance increases to the maximum value within a specific range of the aforementioned ratio.
• the pressure resistance decreases significantly given that the aforementioned ratio exceeds the value at which the pressure resistance increases to the maximum value (i.e., an upper limit value). That is, the upper limit value of the aforementioned ratio is a critical value to increase the pressure resistance, and the upper limit value decreases gradually with a reduction in the bottom depth DD.
• ratios of the pressure resistance to the maximum value thereof are also listed.
• the curvature radius ratio (Ra/Rb) at which the ratio of the pressure resistance is about 3% less than the maximum value that is, the ratio of the pressure resistance to the maximum value is about 97%
• the curvature radius ratio at which the pressure resistance is about 97% is employed as the lower limit value.
• the lower limit value of the curvature radius ratio is set to the value at which the ratio of the pressure resistance to the maximum value is "about 97%".
• can bodies having a shape shown in FIG. 1 were prepared using a thin metal sheet (aluminum-alloy sheet) whose thickness was 0.215 mm.
• the diameter D4 i.e., a grounding diameter
• the bottom depth DD was also varied to 11.7 mm, 11.4 mm, 11.1 mm, and 10.8 mm.
• the doming punch 8 shown in FIG. 2 ) whose outer diameter DP was 43.14 mm was used to manufacture the can bodies. As described, the outer diameter DP corresponds to the diameter DP of the domed section 5.
• the height Y of the domed section 5 was 7.01 mm. In the can body in which the bottom depth DD was 11.4 mm, the height Y of the domed section 5 was 6.66 mm. In the can body in which the bottom depth DD was 11.1 mm, the height Y of the domed section 5 was 6.31 mm. In the can body in which the bottom depth DD was 10.8 mm, the height Y of the domed section 5 was 5.97 mm.
• the curvature radius Ra of the first arcuate portion 5A and the curvature radius Rb of the second arcuate portion 5B were varied to the extent that the arcuate portions 5A to 5C are joined smoothly to form a curved surface protruding upwardly.
• the examination was conducted to measure pressure resistance of each of the can bodies by pressurizing the liquid (i.e., water) held in the can bodies while fixing the rim section 4 from below and from radially outer side.
• the pressure resistance corresponds to the pressure at which the domed section was buckled. That is, the pressure resistance corresponds to the strength of the domed section.
• Measured values of the pressure resistance are indicated in a diagram shown in FIG. 4 .
• the horizontal axis represents the curvature radius ratio (Ra/Rb) between the first arcuate portion 5A and the second arcuate portion 5B
• the vertical axis represents the pressure resistance (MPa) with respect to the curvature radius ratio
• the curve L5 represents measured values of the metal can 1 in which the bottom depth was 11.7 mm
• the curve L6 represents measured values of the metal can 1 in which the bottom depth was 11.4 mm
• the curve L7 represents measured values of the metal can 1 in which the bottom depth was 11.1 mm
• the curve L8 represents measured values of the metal can 1 in which the bottom depth was 10.8 mm.
• the measured values are also shown in Table 4.
• the pressure resistance increases with an increase in the curvature radius ratio, and the pressure resistance increases to the maximum value within a specific range of the curvature radius ratio.
• the pressure resistance decreases significantly given that the aforementioned ratio exceeds the value at which the pressure resistance increases to the maximum value (i.e., an upper limit value). That is, the upper limit value of the curvature radius ratio is a critical value to increase the pressure resistance, and the upper limit value decreases gradually with a reduction in the bottom depth DD.
• ratios of the pressure resistance to the maximum value thereof are also listed.
• the curvature radius ratio (Ra/Rb) at which the ratio of the pressure resistance is about 3% less than the maximum value, that is, the ratio of the pressure resistance to the maximum value is about 97% increases with a reduction in the bottom depth DD.
• the curvature radius ratio at which the pressure resistance is about 97% is employed as the lower limit value for the reason explained in the Example 1.
• the upper limit values and the lower limit values are defined by the oblique sides of the inverted trapezoids. Each range between the oblique sides of the inverted trapezoid individually corresponds to each region enclosed by the thick line in Table 1 and Table 4.
• These expressions are so-called experimental formulas developed based on the results of the foregoing examples taking account of errors caused during a normal manufacturing process. Given that the manufacturing conditions of the metal cans are altered, an actual measurement result may be slightly different from a calculation result. However, such slight difference is tolerable in practical use. Accordingly, the above-listed formulas are applicable for a practical method and process for manufacturing the metal can according to the present invention.
• the ratio between the curvature radius Ra of the first arcuate portion 5A and the curvature radius Rb of the second arcuate portion 5B may be determined arbitrarily using the above-explained formulas. Therefore, the height Y and the diameter DP of the domed section 5 may be varied arbitrarily at the design phase as long as the curvature radius ratio Ra/Rb falls within the range between the lower limit and the upper limit thereof. For this reason, the domed section 5 may be designed geometrically with reference to e.g., the above-mentioned Table 3 and Table 6 such that the first arcuate portion 5A and the second arcuate portion 5B are joined smoothly to each other.
• the shape of the domed section 5 possible to enhance the strength thereof to the maximum may be determined.
• the pressure resistance of the can body was measured while fixing the rim section 4. This is because such pressure resistance of the two-piece metal can to be exerted in the situation where the rim section is fixed correlates with the strength against the impact force applied from the content (or the drop impact strength). That is, the drop impact strength of the metal can may be increased by increasing the pressure resistance to be exerted in the situation where the rim section is fixed.
• the domed section 5 may be designed to enhance the strength thereof to the maximum. For this reason, a thickness of the metal can or the material of the metal can may be reduced thinner than that of the conventional metal can. As a result, it is possible to reduce the cost of the metal can, and the material of the metal can may be saved effectively.
• the metal can and the manufacturing method thereof according to the present invention should not be limited to the foregoing examples.
• a diameter and a height of the domed section, a wall thickness, curvature radii of the arcuate portions may be altered within the scope of the present invention.

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• Engineering & Computer Science (AREA)
• Mechanical Engineering (AREA)
• Containers Having Bodies Formed In One Piece (AREA)
• Shaping Metal By Deep-Drawing, Or The Like (AREA)

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• 2023
  • 2023-02-20 JP JP2023024113A patent/JP2024117983A/ja active Pending
• 2024
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  • 2024-02-08 EP EP24760152.9A patent/EP4640571A1/de active Pending
  • 2024-02-08 CN CN202480013378.7A patent/CN120731173A/zh active Pending
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