JP5456418B2 - Aluminum alloy plate for can body having excellent resistance to distribution pinhole and manufacturing method thereof - Google Patents

Description

  The present invention relates to an aluminum alloy plate for a can body that has excellent flow-resistant pinhole resistance and a method for producing the same.

  In general, the can body includes a can with a can lid wound around its open end and a bottle can with a cap screwed into its open end, filled with beverages and other contents, and distributed in the market. doing. Such a can body is conventionally formed by DI processing performed by drawing and ironing a plate material made of an Al alloy of JIS3004 (AA3004) or JIS3104 (AA3104). Such a ironing process is usually performed in three times to produce a can body. And the trunk | drum of a can body is formed in about 0.106 mm in thickness in the thinnest part, for example, and the difference of tensile strength and 0.2% yield strength shall be 27 Mpa or less.

Conventionally, in the distribution process of the can body as described above, for example, the sharp body contacts or collides with the body portion of the can body, the body portions of adjacent can bodies collide, or between the cans and the cans. Due to rubbing in a state where foreign matter is sandwiched, there is a problem that breakage of a minute hole or the like called a distribution pinhole occurs and the contents leak.
Although it is conceivable to increase the thickness of the barrel as an effective means for solving the above-mentioned problem of pinholes, the material of the can body material can be used even if the barrel thickness is simply increased. Since the amount increases, it cannot be avoided that the manufacturing cost increases.

In order to solve such a problem, for example, it is made of an aluminum alloy material containing Mn: 0.8 to 1.5% and Mg: 0.8 to 1.3% by mass, and the elongation at break is 6 to 10%. % Can bodies have been proposed (for example, Patent Document 1).
In the can body described in Patent Document 1, the material composition of the can body is set as described above, and the elongation at break after making the can is set to 6 to 10%, thereby reducing the thickness of the material. However, it is said that the piercing strength of the trunk portion is improved.

However, in the structure of the can body described in Patent Document 1, when the thickness of the material is reduced, the bottom portion also becomes thin, and the pressure resistance strength of the bottom portion may be reduced. For this reason, it is necessary to increase the strength of the raw material itself. However, if the strength of the raw material is increased, there is a problem in that the body portion is likely to be broken (cut out) during molding by ironing.
In order to prevent such a barrel cut, it is effective to increase the number of ironing processes in order to reduce the ironing rate in one ironing process. However, as described above, it has been conventionally used. In the conventional DI processing method, ironing is usually performed three times, and there is a problem that conventional process equipment cannot be used when the number of times of ironing is increased.

  Therefore, for the purpose of preventing the occurrence of pinholes without increasing the manufacturing cost, the applicant of the present application uses a high-strength and thin-walled material, under the condition of increasing the total drawing ratio when molding into a can body, Research has been conducted on a technique for obtaining a lightweight can having a high pressure resistance at the bottom because the material strength is high even if the thickness of the bottom is thin, and patents have been filed based on the research results (Patent Documents 2, 3, 4). ).

JP-A-8-199273 JP 2007-197815 A JP 2007-197816 A JP 2007-197817 A

  According to the techniques described in these Patent Documents 2 to 4, the alloy composition ratio and thickness of the material, the number of intermetallic compounds, the material yield strength after baking, the tensile strength after processing and baking, the elongation, and the reoil amount By defining the control, plate thickness, drawing ratio and ironing amount, etc., we were able to provide a can body that was relatively lightweight and excellent in circulation pinhole resistance.

However, in order to obtain a can body that is lighter and more resistant to pinholes, as a result of conducting detailed research on materials and manufacturing conditions, the following knowledge has been obtained.
For example, the pinhole resistance can be enhanced by increasing the strength and ductility of the can body. For this purpose, the addition amount of an element for increasing the strength, such as Mg, Cu, or Si, may be increased. Furthermore, if the final cold rolling ratio at the time of manufacturing the material is increased, the strength of the material can be increased, but softening is likely to occur during baking after can molding, and the ductility of the can body after baking is reduced. . Therefore, even if the rolling rate of the material is excessively increased, the effect on the pinhole resistance is small.
However, if the amount of Mg, Cu, Si, etc. is excessively high, cracks will occur at the end of the sheet width during intermediate cold rolling at the time of raw material production, and this crack will be the starting point of the sheet during cold rolling or continuous annealing. Breaking easily occurs. The productivity and yield decrease due to the breakage of the plate is remarkable, so if a crack occurs at the end of the plate, it is necessary to trim the end to remove the crack or add an intermediate annealing to suppress the occurrence of the crack However, productivity and yield reduction due to the addition of these processes also increase costs, and it is considered necessary that cracks are unlikely to occur at the end of the plate.

In addition, if the strength of the material is increased by controlling the conditions such as increasing the amount of the component elements or increasing the final cold rolling rate, there is a problem that cylinder breakage (ie, cylinder breakage) is likely to occur during ironing. is there. Therefore, it is necessary to set the ironing rate to a certain low range in order to suppress torsion.
Next, it is applied when the total drawing ratio is high, and the strength is increased, and a material with a thin plate thickness is used. However, when the material plate thickness is thin, when the plate and punched scrap are conveyed during cup molding, the punched scrap is formed. There was a problem that it could not be transported outside the machine.

  That is, when forming a can body, there is a step of first punching a raw material plate into a disk-shaped blank by a cupping press and forming this into a cup shape. In this process, a material plate wound in a coil shape is attached to a supply device called an uncoiler, and the end of the material plate fed out from the supply device is fed into a cupping press via a lubricator. During blanking and cup molding, the material plate cannot be fed, so after cup molding is finished, the cupping press mold returns to near the top dead center and then the mold is near top dead center. Send a board as a material. At this time, the remaining portion of the plate from which the blank has already been punched is discharged to the outside of the cupping press and cut with a shear cutter during the next press. However, the board (skeleton material) after punching the blank is in a state where a plurality of holes are formed, and it is easy to bend, and if it is bent, it will not be able to be sent out of the cupping press normally. If it remains in the molding area of the cupping press, there is a problem of hindering the next pressing step. The present inventors refer to this state as a skeleton jam, but when a skeleton jam occurs, the cupping press must be temporarily stopped to discharge the skeleton material, resulting in a problem that the production efficiency is lowered.

  The remaining skeleton material for this forming area is the detailed shape of the skeleton material after blanking, the flatness, the viscosity of the applied lubricant, and the form of the part supporting the plate or skeleton material in the cupping press However, as the plate is thinner, the skeleton material tends to remain in the cupping press. In addition, as a result of the inventor's actual research, when the strength of the plate is high, it has been found that the skeleton material hardly remains in the forming area of the cupping press even if the plate thickness is thin. When the material strength is less than 0.27 mm, the knowledge of how much the material proof stress is can suppress the residual of the skeleton material has been obtained.

  The present invention has been made in view of the above circumstances, and in addition to the contents of Mn, Mg, Si, Fe, Cu, the amount of (Si + Cu) is controlled, and further, the material tensile strength, material yield strength, after baking In addition to controlling the material characteristics and the characteristics of the material such as the tensile strength and elongation of the body after making the can, the important parameters when designing the can body are the material thickness, total ironing ratio, and total drawing ratio. An aluminum alloy plate for a can body that can suppress the occurrence of cracks during rolling, reduce the rate of occurrence of cylinder breakage, and increase the piercing strength by controlling the thickness of the body and its manufacturing method The purpose is to provide.

In order to solve the above problems, the present invention employs the following configuration.
The aluminum alloy plate for a can body having excellent flow-resistant pinhole resistance according to the present invention has a body thickness of 0.096 mm to 0.113 mm and a total drawing ratio of 2.2 to 2.7 at the time of manufacture. There is an aluminum alloy plate for a can body used for manufacturing a can body having a total ironing ratio of 60% or less, and in terms of mass%, Mn: 0.8 to 1.1%, Mg: 1.3 to 1. 7%, Si: 0.25 to 0.45%, Fe: 0.3 to 0.55%, Cu: 0.25 to 0.45%, Si + Cu: 0.6 to 0.8% , Zn: 0 .30% or less, Ti: 0.15% or less , the balance is made of Al containing inevitable impurities, the plate thickness is 0.240 mm or more and 0.265 mm or less, and the material tensile strength is 325 MPa or less. The yield strength is 285 MPa or more and 310 MPa or less, and the material elongation is 2.5% or more. 5% or less, yield strength after baking is 280 MPa or more, post-baking (ABTS)-(ABYS) value is 35 MPa or more, tensile of body part of can body after canning by DI processing and paint baking The strength is 350 MPa or more and 410 MPa or less, the elongation of the body is 4.5% or more, the change in TS due to baking (AB TS) − (H TS) is 10 MPa or more, and the change in YS due to baking. The value of (H YS-AB YS) is 10 MPa or less.

Aluminum alloy sheet for a can body having excellent fluid-tight communication pinhole characteristic of the present invention, the circle equivalent diameter of 1 or more 10μm or less of the intermetallic compound is 3000 / mm ² or more 4800 / mm ² or less in area ratio 1. It is characterized by being 5% or more and 2.5% or less.

  In the method for producing an aluminum alloy plate for a can body according to the present invention, the thickness of the body portion is 0.096 mm or more and 0.113 mm or less, and the total drawing ratio during production is 2.2 or more and 2.7 or less, And in order to manufacture the aluminum alloy plate for can bodies used for manufacture of the can body whose total ironing rate is 60% or less, Mn: 0.8-1.1%, Mg: 1.3-1. 7%, Si: 0.25 to 0.45%, Fe: 0.3 to 0.55%, Cu: 0.25 to 0.45%, Si + Cu: 0.6 to 0.8%, A method for producing an aluminum alloy sheet for a can body that is subjected to a homogenization treatment of an aluminum alloy cast material containing the inevitable impurities in the balance, followed by a hot rolling process and a cold rolling process. Intermediate annealing is performed by heating to a temperature of 600 ° C. or lower for a predetermined time, and then By performing cold rolling at 0% or more and 70% or less, the plate thickness is 0.240 mm or more and 0.265 mm or less, the material tensile strength is 325 MPa or less, the material yield strength is 285 MPa or more and 310 MPa or less, and the material elongation is 2 0.5% or more and 4.5% or less, the yield strength after baking is 280 MPa or more, and the value of (ABTS)-(AB YS) after baking is 35 MPa or more, after making cans by DI processing and paint baking The tensile strength of the body part of the can body is 350 MPa or more and 410 MPa or less, and the elongation of the body part can be 4.5% or more.

In order to improve the distribution pinhole resistance of the can body, it is most effective to increase the thickness of the body portion of the can body. On the other hand, when the plate thickness of the body portion is increased, the necessary amount of can body material necessary for can making increases, which is not economical.
Therefore, it is necessary to reduce the amount of can body material required by forming the bottom of the can body thin. Since the bottom of the can body is not ironed, it is necessary to reduce the material plate thickness in order to make the bottom thinner. Moreover, since the pressure resistance strength of the bottom portion decreases when the bottom portion becomes thin, it is necessary to increase the strength of the material itself. However, when the strength of the material is increased, the body portion is likely to be broken (runout) during ironing.

  As a result of intensive studies by the present inventors, it is possible to reduce the total ironing rate by forming the plate thickness of the material to an appropriate range and by forming the plate thickness of the can body barrel portion made thick. It was found that it was possible to suppress the occurrence of torsion to the same level as before even if the strength of the material was increased. It was also found that by increasing the strength of the material, the strength of the can body body after canning by DI processing and paint baking can be increased, so that pinholes are less likely to occur.

  As described above in detail, according to the present invention, in addition to controlling the contents of Mn, Mg, Si, Fe, and Cu in a preferable range, the amount of (Si + Cu) is controlled, By controlling the material tensile strength, material yield strength, material properties after baking, and the tensile strength and elongation of the barrel after canning, the occurrence of cracks during rolling is suppressed, the rate of occurrence of cylinder breakage is kept low, and the piercing strength There is an effect that an aluminum plate for a can body having a higher height can be obtained.

FIG. 1 is a schematic view for explaining a process when a can body is manufactured by performing DI processing on an aluminum alloy plate for a can body according to the present invention. FIG. 2 is a partially enlarged longitudinal sectional view of the can body shown in FIG.

Hereinafter, an embodiment of an aluminum alloy plate for a can body (hereinafter, may be abbreviated as an aluminum alloy plate for a can body) having excellent flow-resistant pinhole properties according to the present invention will be described.
The aluminum alloy plate for a can body of the present embodiment has a body thickness of 0.096 mm to 0.113 mm, a total drawing ratio of 2.2 to 2.7, and a total ironing rate. An aluminum alloy plate for a can body used for producing a can body of 60% or less, and by mass%, Mn: 0.8 to 1.1%, Mg: 1.3 to 1.7%, Si: 0.00. Al containing 25 to 0.45%, Fe: 0.3 to 0.55%, Cu: 0.25 to 0.45%, Si + Cu: 0.6 to 0.8%, and the balance containing inevitable impurities The sheet thickness is 0.240 mm or more and 0.265 mm or less, the material tensile strength is 325 MPa or less, the material yield strength is 285 MPa or more and 310 MPa or less, and the material elongation is 2.5% or more and 4.5% or less, Yield after baking is 280 MPa or more, baking The value of (AB TS)-(AB YS) is 35 MPa or more, the tensile strength of the body portion of the can body after can manufacturing by DI processing and paint baking is 350 MPa or more and 410 MPa or less, and the elongation of the body portion is 4.5% or more,
TS change due to baking (AB TS)-(H TS) value of 10 MPa or more, YS change due to baking (H YS-AB YS) value of 10 MPa or less, can body after can manufacturing by DI processing and paint baking The barrel portion has a tensile strength of 350 MPa or more and 410 MPa or less, and the barrel portion has an elongation of 4.5% or more. In addition to the above-mentioned rules, the aluminum alloy plate for can bodies of the present embodiment more preferably has a can body elongation of 5% or more after can making.

In addition to the above-mentioned rules, the aluminum alloy plate for a can body of the present embodiment further has an inter-metallic compound having an equivalent circle diameter of 1 to 10 μm of 3000 / mm ^{2 to} 4800 / mm ² and an area ratio of 1. It is preferably 5% or more and 2.5% or less.

[Method for producing aluminum alloy sheet]
The aluminum alloy plate for can bodies according to the present invention is manufactured through ordinary melting, casting, homogenization treatment, hot rolling, and cold rolling applied when manufacturing this type of aluminum alloy. Moreover, it is preferable to perform the annealing which heats to the temperature of 400 degreeC or more and 600 degrees C or less for 1 second or more and 2 minutes or less between the passes of cold rolling. In particular, the intermediate sheet is heated at a temperature of 450 ° C. or higher and 600 ° C. or lower for 1 second or more between cold rolling passes, and then the final cold rolling of 50% to 70% is performed, whereby the final plate as a material is obtained. Thickness (0.240 mm or more and 0.265 mm or less), (AB TS: Tensile strength after baking)-(AB YS: Yield strength after baking) is 35 MPa or more, (AB TS)-(H TS: material An aluminum alloy plate having a tensile strength of 10 MPa or more and (H YS: material yield strength) − (AB YS) of 10 MPa or less (including negative) can be produced.
In addition, a homogenization process can be performed with respect to an aluminum alloy ingot in the temperature range of 560 degreeC-less than melting | fusing point.

[Ingredient composition]
Hereinafter, the component composition limited in the aluminum alloy plate for can bodies of this invention is demonstrated. In addition, content of each element described below is mass% unless otherwise specified, and includes an upper limit and a lower limit unless otherwise specified. Therefore, for example, the notation of 0.8 to 1.1% means 0.8% or more and 1.1% or less.

"Si" 0.25-0.45%
In the aluminum alloy plate for can bodies of the present invention, Si forms a compound together with Mg or the like contained at the same time, and improves the strength by solid solution hardening, precipitation hardening and dispersion hardening, and Al-Fe-Mn metal It is contained in the intermetallic compound and has the effect of preventing seizure on the die during ironing.
If the Si content is less than 0.25%, sufficient strength cannot be obtained, and the intermetallic compound size increases. If the Si content exceeds 0.45%, the strength becomes too high, and when a can body is produced, it becomes easy to cause a barrel cut, and the workability deteriorates. Moreover, the intermetallic compound with Mg, Cu, and Al cannot be solutionized, the toughness is lowered, and pinholes are easily generated. Therefore, the Si content is preferably in the range of 0.25 to 0.45%.
"Fe" 0.3-0.55%
Fe increases the precipitation amount of Al-Mn-Fe intermetallic compounds in the aluminum alloy sheet for can bodies of the present invention, and prevents the formation of fine crystals and seizure to the die during ironing processing. Has the effect of
If the Fe content is less than 0.3%, the amount of Al—Mn—Fe intermetallic compound deposited becomes too small, and seizure to the ironing mold tends to occur. When the content of Fe exceeds 0.55%, the amount of Al—Mn—Fe intermetallic compound becomes too large, workability deteriorates due to a decrease in toughness, and pinholes are likely to occur. Therefore, the Fe content is preferably in the range of 0.3 to 0.55%.

“Cu” 0.25 to 0.45%
Cu forms an intermetallic compound with Mg or the like in the aluminum alloy plate for a can body of the present invention, and has an effect of increasing strength by solid solution hardening, precipitation hardening, and dispersion hardening.
If the Cu content is less than 0.25%, a sufficient strength improvement effect cannot be obtained. If the Cu content exceeds 0.45%, side cracks are likely to occur, the rollability is lowered, the strength becomes too high, and the body is easily cut when it is made as a can body. In addition, the intermetallic compound with Mg, Si, and Al cannot be in solution, and the workability deteriorates due to a decrease in toughness, and pinholes are likely to occur. Therefore, the Cu content is preferably in the range of 0.25 to 0.45%. Also within this range, a range of 0.3 to 0.45% is more preferable.
"Si + Cu"
In this embodiment, Si + Cu which is the total value of the Si amount and the Cu amount is also defined. If the amount of Si + Cu is less than 0.6%, it is difficult to obtain sufficient strength, and if the amount of Si + Cu exceeds 0.8%, side cracks are likely to occur, and the rollability is lowered and the strength is too high. When it is made as a can body, it becomes easy for the body to be cut.

"Mn" 0.8-1.1%
In the aluminum alloy plate for can bodies of the present invention, Mn forms an Al-Mn-Fe intermetallic compound, becomes a crystallization phase and a dispersed phase, exhibits a dispersion hardening action, and is used as a die during the ironing process. On the other hand, it has the effect of preventing seizure.
When the content of Mn is less than 0.8%, the amount of Al—Mn—Fe intermetallic compound becomes too small to obtain sufficient curing characteristics, and seizure to the ironing mold is likely to occur. . When the content of Mn exceeds 1.1%, the amount of Al—Mn—Fe intermetallic compound becomes too large, workability deteriorates due to a decrease in toughness, and pinholes are likely to occur. Therefore, the Mn content is preferably in the range of 0.8 to 1.1%.

"Mg" 1.3-1.7%
In the aluminum alloy plate for can bodies of the present invention, Mg has a solid solution strengthening action, enhances work hardening at the time of rolling, and exhibits dispersion hardening and precipitation hardening action by coexisting with Si and Cu. To improve.
If the Mg content is less than 1.3%, sufficient strength cannot be obtained. If the Mg content exceeds 1.7%, side cracks are likely to occur, the rollability is lowered, the strength is too high, the workability is lowered, and the can is cut as a can body. Is likely to occur. Therefore, the Mg content is preferably in the range of 1.3 to 1.7%. Even within this range, the Mg content is more preferably in the range of 1.4 to 1.7%.

“Zn and Ti” Zn: 0.30% or less, Ti: 0.15% or less The aluminum alloy plate for a can body of the present invention may further contain, if necessary, Zn: 0.30% or less, and Ti: It can be set as the component composition containing 1 type or 2 types in 0.15% or less.
Zn has the effect of refining the precipitated intermetallic compounds of Mg, Si, and Cu. However, when Zn is contained, used aluminum cans and recycled materials can be effectively used as raw materials. When the Zn content exceeds 0.30%, the corrosion resistance deteriorates. Therefore, the Zn content is preferably 0.30% or less.
Ti has the effect of refining crystal grains and improving workability in the aluminum alloy plate for can bodies of the present invention. When the Ti content exceeds 0.15%, the amount of intermetallic compounds increases so much that the toughness decreases and pinholes are likely to occur. Therefore, the Ti content is preferably 0.15% or less.
Also, other elements may be contained as 0.05% or less as impurities.

[Number of intermetallic compounds]
In the aluminum alloy plate for a can body of the present invention, the number of intermetallic compounds having an equivalent circle diameter of 1 to 10 μm is preferably 3000 / mm ² or more and 4800 / mm ² or less. The distribution of intermetallic compounds within this range can be obtained by defining the component composition as described above and performing homogenization treatment on the aluminum alloy ingot at a temperature of 560 ° C. to less than the melting point.
When the number of intermetallic compounds is less than 3000 / mm ² , the amount of intermetallic compounds becomes too small, and seizure to the ironing mold tends to occur.
When the number of intermetallic compounds exceeds 4800 / mm ² , the amount of intermetallic compounds becomes too large, the toughness is lowered, and pinholes are likely to occur. The number of intermetallic compounds is more preferably 4400 / mm ² or less.

[Area ratio of intermetallic compounds]
In the can body aluminum alloy plate of the present invention, the area ratio of the intermetallic compound having an equivalent circle diameter of 1 to 10 μm is preferably 1.5 to 2.5%.
When the area ratio of the intermetallic compound is less than 1.5%, the amount of the intermetallic compound becomes too small, and seizure to the ironing mold is likely to occur. When the area ratio of the intermetallic compound exceeds 2.5%, the amount of the intermetallic compound is excessively increased, the toughness is lowered, and pinholes are easily generated. The area ratio of the intermetallic compound is more preferably 2.2% or less.

[Tensile properties of materials]
The yield strength (H YS) of the material is preferably 285 MPa or more. When the proof stress is less than 285 MPa, when a blank is punched out from a plate as a material by a cupping press, the skeleton material after punching out the blank remains in the cupping press, which tends to adversely affect the subsequent press process. Become. Further, when the tensile strength (HTS) of the material exceeds 325 MPa, or when the material yield strength exceeds 310 MPa, it becomes easy to cause a cylinder breakage.
[Material elongation]
The material elongation is in the range of 2.5 to 4.5%. When the material elongation is less than 2.5%, a process of forming a cup-shaped can body having the shape shown in FIGS. 1B to 1C described later, or the bottom portion 12 of the can body 10 shown in FIG. 2 is formed. Sometimes it tends to break easily. On the other hand, when the material elongation exceeds 4.5%, it tends to be easily cut off.

[Thickness of aluminum alloy sheet for can body]
The plate thickness of the aluminum alloy plate for can bodies of the present invention is preferably in the range of 0.240 mm or more and 0.265 mm or less.
When the plate thickness is less than 0.240 mm, sufficient pressure resistance strength cannot be obtained when a can is made into a can body. On the other hand, if the plate thickness exceeds 0.265 mm, the weight of the bottom of the can body becomes heavy and the manufacturing cost increases, which is not economical. In particular, the plate thickness is preferably in the range of 0.240 mm to 0.265 mm.

[Reoil amount]
In the aluminum alloy plate for can bodies of the present invention, it is preferable to reoil (coat) 50 to 300 mg / m ² of lubricant on the surface of the plate after cold finish rolling. For the reoil, a lubricant having a high affinity with the lubricant applied immediately before deep drawing may be used. For example, the same lubricant as that applied immediately before deep drawing may be used.
By pre-lubricating a small amount of lubricant on the alloy plate material in advance, it will be applied evenly when applying the lubricant immediately before deep drawing, and during deep drawing and ironing The lubrication effect is enhanced, and it is possible to suppress the cylinder breakage particularly during ironing.
The reoil amount is preferably in the range of 50 to 300 mg / m ² . If it is this range, the above-mentioned effect is fully acquired.
Further, the reoil amount is more preferably 50 to 200 mg / m ² .

[Material strength after baking (210 ° C x 10 minutes)]
The can body after DI processing is heated to a temperature of 180 to 230 ° C. by drying after cleaning and chemical conversion treatment, or by baking treatment after external printing or internal coating. This heating generally changes the strength of the can bottom and the trunk. The strength after heating differs depending on the amount of strain during DI molding. Since the distortion at the bottom is small during DI molding, the strength after heating is almost equal to the strength after heating the aluminum alloy plate, which is a material before DI processing. For this reason, the intensity | strength after baking (heating) the aluminum alloy plate which is a raw material can be used as a standard of the intensity | strength of a bottom part. In the present invention, the heating condition for this is 210 ° C. × 10 minutes.
The material yield strength (AB YS) after baking of the aluminum alloy plate for a can body of the present invention is preferably 280 MPa or more after being baked under the above conditions.
If the material yield strength after baking under the above-mentioned conditions is less than 280 MPa, sufficient pressure strength of the can body after canning by DI processing and paint baking cannot be obtained.

[Changes in TS and YS due to baking]
The material tensile strength after baking is expressed as (ABTS). The change in TS due to baking (AB TS)-(H TS) and the change in YS due to baking (H YS-AB YS) will be described. A material having a large decrease in yield strength is unlikely to have high tensile strength and elongation even if the material strength is increased. Furthermore, even if the tensile strength of the can body is increased, the piercing strength does not increase so much. On the other hand, in order to increase the piercing strength, it is necessary to excessively increase the tensile strength and elongation of the material, and the barrel breakage is remarkably likely to occur during ironing. That is, it is impossible to achieve both torsional puncture strength and piercing strength.
Taking these into consideration, it is preferable that the value of TS change due to baking (AB TS) − (H TS) is 10 MPa or more and the value of YS change due to baking (H YS−AB YS) is 10 MPa or less.

[After baking (AB TS)-(AB YS)]
Explaining the value of (AB TS)-(AB YS) after baking, when this value is low, the work hardening ability is lowered, the can body tensile strength and ductility after can making are lowered, and pinholes are generated. It becomes easy. In order to increase the value of (AB TS) − (AB YS), the final cold rolling rate may be decreased. However, if the final cold rolling rate is decreased, AB YS is also decreased. In order to obtain the above, it is effective to increase the components such as Mg, Cu, and Si and / or perform intermediate annealing at a high temperature to form a solution of Mg, Cu, and Si.
By such a method, intermediate annealing is performed by heating at a temperature of 450 ° C. or higher and 600 ° C. or lower for 1 second or more between cold rolling passes, and then 50% to 70% of the final cold rolling is performed. The value of (AB TS) − (AB YS) after baking can be set to 35 MPa or more. In particular, the value of (AB TS) − (AB YS) after baking is more preferably 37 MPa or more.

[About the total ironing ratio and the total drawing ratio]
The aluminum alloy plate for a can body of the present invention is used for manufacturing a can body having a body thickness (thinnest portion thickness) of 0.096 mm or more and 0.113 mm or less. In particular, it is suitable for use in manufacturing a can body having a body thickness of 0.110 mm or less. Moreover, the aluminum alloy plate for can bodies of the present invention is used for manufacturing a can body having a total ironing rate during DI processing of less than 60%. Here, the total ironing rate is expressed by the following equation (1).
Total ironing rate (%) = {(original plate thickness T1−final can body body thinnest portion thickness T2) / original plate thickness T1} × 100 (1)
In the above formula (1), the final can body body thinnest portion thickness T2 is a thickness without a coating film. The aluminum alloy plate for a can body of the present invention has a material plate thickness of 0.240 mm or more and 0.265 mm or less. For example, the ironing rate is 0.240 mm for the original plate thickness and 0.096 mm for the body thickness. 60%.

Here, when the total ironing ratio exceeds 60%, the aluminum alloy sheet for can bodies of the present invention has high material strength, and thus the body is likely to be cut during ironing forming, and the productivity is lowered.
When the material plate thickness is smaller than 0.240 mm, sufficient pressure strength cannot be obtained. Further, when the body plate thickness is larger than 0.113 mm, the pinhole resistance is improved, but from the practical viewpoint, it becomes excessive strength and the amount of necessary material increases, which is not economical.
Moreover, the aluminum alloy plate for can bodies of the present invention is used for manufacturing a can body having a total drawing ratio of 2.2 to 2.7 during DI processing.
If the total drawing ratio is greater than 2.7, the material is likely to break during drawing when drawn in two drawing steps. On the other hand, in order to obtain a can body having a practical capacity under the constraints of the material plate thickness T1, the final can body body thinnest part thickness T2, and the total ironing rate, the total drawing ratio should be 2.2 or more. There is a need to. For example, when a can body having a can body diameter of 66 mm and a capacity of 350 cc, which is generally used, is formed, the total drawing ratio is preferably set to 2.2 to 2.4. Further, when a can body having a can body diameter of about 66 mm and a capacity of about 500 cc is molded, the total drawing ratio is preferably set to 2.45 to 2.65.

Here, the total drawing ratio A is obtained by multiplying the cup drawing ratio B (steps of FIGS. 1A to 1B) and the redrawing ratio C (steps of FIGS. 1B to 1C). It is a value and is represented by the following formulas (2) to (4).
Cup drawing ratio B = blank diameter D1 / cup diameter D2 (2)
Redrawing ratio C = cup diameter D2 / body diameter D3 (3)
Total drawing ratio A = Cup drawing ratio B × Redrawing ratio C = Blank diameter D1 / Body diameter D3 (4)

[Tensile strength of can body body after canning by DI processing and paint baking]
It is preferable that the tensile strength of the body part of the can body obtained by performing DI processing and paint baking of the aluminum alloy plate for can bodies of the present invention is 350 MPa or more and 410 MPa or less.
If the tensile strength of the body of the can body after canning by DI processing and paint baking is less than 350 MPa, sufficient flow-resistant pinhole properties cannot be obtained. At the same time, productivity decreases.

[Elongation of can body after can making by DI processing and paint baking]
The elongation of the body portion of the can body obtained by DI processing and paint baking of the aluminum alloy plate for can bodies of the present invention is preferably 4.5% or more, and most preferably 5% or more.
The body portion immediately after DI molding has low elongation and is fragile, so pinholes are likely to occur. The molded can body is dried by washing and chemical conversion treatment, and is heated by baking after the outer surface coating printing and inner surface coating, whereby the ductility is restored although the strength is lowered.
By controlling the heating conditions as described above, it is necessary to make the elongation of the body portion equal to or more than the lower limit. However, for example, when heating at a constant temperature for 10 minutes, a temperature of 180 ° C. is not sufficient. It is necessary to heat at a temperature of 190 ° C. or higher.

[Can manufacturing process by DI processing]
Hereinafter, an example of a process of obtaining a can body 10 by performing DI processing on an aluminum alloy material for a can body to produce a can body 10 will be described with reference to FIG.
First, as shown in FIG. 1 (a), a can body aluminum alloy material is punched to obtain a disk-shaped plate material (blank) having a diameter of 149 mm.
Next, the disk-shaped plate member is drawn to form a cup-shaped can body having a height in the axial direction of approximately 42 mm and an outer diameter of 88.2 mm as shown in FIG. Here, the disc-shaped plate material has a thickness of 0.240 mm or more and less than 0.265 mm.

Next, the cup-shaped can body is redrawn to obtain a cup-shaped can body having an outer diameter of 66 mm as shown in FIG. Here, the ratio of D1 and D3 is set to 2.2 to 2.7.
Next, ironing is performed so that the total ironing rate is less than 60%, thereby forming a bottomed cylindrical can body as shown in FIG. The opening end portion of the bottomed cylindrical body has an uneven shape that undulates in the direction of the can axis.

Next, the open end of the bottomed cylindrical body shown in FIG. 1 (d) is cut so that the size in the can axis direction, that is, the height is equal to about 123.5 mm over the entire circumference. A can body 10 having a circular cross section shown in FIG. 1 (e) having a body portion 11 and a bottom portion 12 having a diameter of 65 mm or more and 67 mm or less is formed.
In this example, as shown in FIG. 2, the bottom portion 12 includes a dome portion 12 a that is recessed toward the inside in the can axis direction of the trunk portion 11, and the outer peripheral edge portion of the dome portion 12 a is a can shaft of the trunk portion 11. It is set as the cyclic | annular convex part 12c which protrudes toward the outer side in a direction. When the can body 10 is placed on the ground surface L so that the can body 10 is in an upright posture, the top portion of the annular convex portion 12c is a grounding portion 12b in contact with the ground surface L. The

As described above, according to the aluminum alloy plate for can bodies excellent in flow-resistant pinhole property of the present embodiment, the component composition is within the above range, and the thickness of the material is 0.240 mm or more and 0.265 mm. It is possible to reduce the total ironing rate to 60% or less by configuring the body thickness of the can body that is made as thin as below and having a thickness of 0.096 mm or more and 0.113 mm or less. For this reason, it becomes difficult for the torso to be cut. Thereby, even when the strength of the material is increased to 285 MPa or more in terms of the material yield strength, it is possible to suppress the occurrence of torsion. However, when the material proof stress exceeds 310 MPa, it is easy for the body to be cut out. Therefore, the upper limit of the material proof stress needs to be 310 MPa or less.
In addition, by increasing the material strength, the strength of the can body barrel after canning by DI processing and paint baking can be increased to 350 MPa or more and 410 MPa or less in tensile strength, so the piercing strength of the barrel improves. The pinhole can be suppressed from being generated in the body portion.
Further, by reducing the thickness of the material plate, the weight of the can body can be suppressed to the same level as in the past.
Therefore, by using the aluminum alloy plate for a can body of the present invention, a can body excellent in circulation pinhole resistance can be obtained without increasing the production cost.

Hereinafter, although an Example is shown and the aluminum alloy plate for can bodies excellent in the distribution | circulation resistance pinhole property of this invention is demonstrated in more detail, this invention is not limited to this Example.
In this example, No. 1 to No. 25 aluminum alloy plates for can bodies were produced in the following steps under the respective component compositions and production conditions shown in Table 1 below, and evaluation was performed for each item described below. .

[Production process of aluminum alloy plate for can body]
An aluminum alloy containing the components shown in Table 1 below was melted, the molten metal was degassed and inclusions removed by conventional methods, and a slab having a thickness of 550 mm, a width of 1.5 m, and a length of 4.5 m was obtained by semi-continuous casting. Cast into. Next, the slab was subjected to a soaking treatment at 565 ° C. and then hot-rolled. The steel sheet was rolled to a thickness of 7.5 mm by hot rolling, and then cold-rolled to a predetermined thickness of 0.65 mm to 0.75 mm. After that, continuous annealing (IA-CAL) is performed in a temperature range of 480 ° C. to 590 ° C. for 1 s to 60 s, followed by cold rolling to a final thickness of 0.260 mm to obtain No. 1 to 19 samples. . Further, after hot rolling from a molten metal having the same composition as described above, it is cold-rolled to a final sheet thickness of 0.260 mm and rolled while performing continuous annealing between hot-rolling and cold-rolling No. 20- Samples No. 24 and 25 were obtained without annealing.

For each sample of an aluminum alloy plate for a can body obtained as described above, an SEM image and a composition image are image-analyzed using EPMA (Electron Probe Micro Analyzer), and an intermetallic compound containing Mn is measured. Thus, the number and area ratio of intermetallic compounds having an equivalent circle diameter of 1 to 10 μm were examined. At this time, the surface of each sample was polished until the rolling marks disappeared, and then the image was observed from the direction perpendicular to the surface of the alloy plate for analysis.
Moreover, about each sample of the aluminum alloy plate for can bodies, the JIS5 test piece was extract | collected so that a tension direction might become parallel with a rolling direction, about a raw material, it used for a tensile test as it is, and about 210 degreeC about the raw material after baking For 10 minutes after heating (after baking).

[Can body manufacturing]
The aluminum alloy plates for can bodies of the examples and comparative examples obtained in the above-described steps were punched out to obtain a disk-shaped plate material having a diameter of 149 mm (see FIG. 1 (a)). This disk-shaped plate material was subjected to DI processing to obtain can bodies (350 cc cans) of Examples and Comparative Examples. In this case, the total drawing ratio and the total ironing ratio are 2.258 and 57.7%, respectively. In addition, the thickness of the can body of the obtained can body is 0.110 mm.

The can body of each of the examples and comparative examples subjected to DI processing as described above was subjected to outer surface coating, outer surface printing, and inner surface coating by the method described below.
First, an epoxy paint and an acrylic paint were used as paints, and applied to the outer surface of the can body at a film thickness of 50 mg / dm ² including printed portions such as character information. And this can body was put into oven and heat-dried at the temperature of 180 degreeC for 30 second.
Moreover, the epoxy paint was apply | coated by the film thickness of 40 mg / dm < ² > using the spray to the inner surface of the can body which gave the outer surface coating as mentioned above. And this can body was put into oven and heat-dried at the temperature of 200 degreeC for 60 second.
[Evaluation of emissions of skeleton materials]
In addition, when blanks are punched from aluminum alloy plates for can bodies, testing is performed with a high feeding speed of the cupping press, and the remaining plate (skeleton material) after punching the blank is smoothly discharged from the cupping press. It was investigated whether there was a phenomenon that could not be done. The results were investigated as the presence or absence of skeleton jam.

[Can body evaluation items]
About the can body of each Example obtained by the above-mentioned process and the comparative example, tensile strength TS in the trunk | drum of a can body, elongation rate, and piercing strength were measured.
Tensile strength TS and elongation rate were obtained by taking a tensile test piece from a position inclined 45 ° from the rolling direction of the bottom of the can body of each sample, total length 75 mm, parallel part length 36 mm, parallel part width 10 mm, grip part width 15 mm. Evaluation was performed using a test piece processed into a shape with a shoulder radius of 15 mm. At this time, the portion 60 mm away from the can's ground contact portion in the upper direction of the can axis was the center of the tensile test piece, and the tensile direction was the can axis direction. Then, after the coating of the outer surface and the inner surface was removed using nitric acid, the tensile strength (TS) and the elongation were measured by performing a tensile test.
Further, the piercing strength is a state in which an internal pressure of 0.196 MPa is applied to the can body in a room temperature (20 ° C.) atmosphere, and the portion of the can body trunk that is 60 mm away from the grounding portion in the upper direction of the can axis, and A position inclined 45 ° from the rolling direction of the bottom of the can was pressed inward in the radial direction with a presser having a radius of curvature (tip radius) of 0.5 mm, and evaluation was performed by the pressing force when a hole was formed. At this time, the moving speed of the body of the presser toward the inside in the radial direction was set to 25 mm / min.

[Rollability evaluation]
For the samples No. 1 to 19, the rolling properties were evaluated. The plate rolled to 7.5 mm by hot rolling was trimmed with a trimmer at the end immediately before winding into a coil after rolling. The end face temperature of the coiled coil was set to 420 to 440 ° C., and recrystallization was caused until the coil was cooled to make it soft. Next, it was cold-rolled to 2.2 mm, both sides of the plate were trimmed by 30 mm, and it was confirmed that no cracks remained on the end face after trimming. Then, it cold-rolled to the predetermined | prescribed plate | board thickness between 0.65-0.75mm. And the crack generation condition of the trim end surface after rolling was confirmed. Next, when rolling from 2.2 mm to 0.65 mm to 0.75 mm, when the plate breaks and when no breakage occurred, the crack after rolling was large and stable in mass production. A case where it was judged that production was not possible was regarded as a failure.

[Evaluation of tornness]
First, 50,000 cans were continuously formed, and it was examined whether or not the body portion was broken during ironing. When the number of torso cuts was 5 cans or more, the occurrence rate was determined from the number of occurrences and the number of cans produced. When the number was less than 5 cans, 50,000 cans were further molded to determine the number of barrel breaks. Then, the rate of occurrence of cylinder shortage = the total number of cylinder cuts / the total number of moldings.

Tables 1 to 3 show the composition components, production conditions, and evaluation test results of Examples and Comparative Examples.
In addition, IA-CAL shown in the column of intermediate annealing in Table 1 indicates that continuous intermediate annealing was performed between cold rolling and cold rolling in the alloy plate manufacturing process, and HOT-CAL Shows that continuous annealing was performed between hot rolling and cold rolling in the alloy plate manufacturing process.
In addition, since the skeleton jam was likely to occur for the samples No. 5, 22, and 25, the molding speed was changed for the materials shown in Table 4 below, and the speed at which stable production was possible without causing the skeleton jam was investigated. It was. In Sample No. 26, (3) is shown together with an alloy having the same component as that of the No. 3 sample and manufactured by substantially the same manufacturing method. About the manufacturing method, in order to obtain the characteristic equivalent to the sample of No. 3, in order to make the final cold rolling rate the same with changing the final plate thickness, the intermediate annealing plate thickness was changed. Hereinafter, the meanings of the numbers in parentheses of the samples Nos. 27 to 33 are the same.

  From the results shown in Tables 1 to 3, conditions desirable in the present invention, that is, in mass%, Mn: 0.8 to 1.1%, Mg: 1.3 to 1.7%, Si: 0.25 0.45%, Fe: 0.3-0.55%, Cu: 0.25-0.45%, Si + Cu: 0.6-0.8%, the balance is made of Al containing inevitable impurities The plate thickness is 0.240 mm or more and 0.265 mm or less, the material tensile strength (TS) is 325 MPa or less, the material yield strength (YS) is 285 MPa or more and 310 MPa or less, and the material elongation is 2.5% or more 4 .5% or less, yield strength after baking (AB YS) is 280 MPa or more, and (AB TS)-(AB YS) value after baking is 35 MPa or more. Can after making can by DI processing and paint baking Tensile strength of body body (TS after canning Is 350 MPa or more and 410 MPa or less, and the elongation of the body portion (elongation after canning) is 4.5% or more, and the change in TS due to baking (ABTS) − (HTS) is 10 MPa or more. It was found that if the value of the change in YS (H YS-AB YS) is 10 MPa or less, the piercing strength is high, cracks are difficult to occur during rolling, the rate of occurrence of cylinder breakage is low, and skeleton jam does not occur.

In Table 1, for each sample in which the amount of each element component is out of the range described in claim 1 of the present invention, each column in Table 1 is marked with *. In Table 2, other conditions (material TS, material YS, material elongation, YS after baking, (AB TS)-(AB YS) value after baking, TS after canning, elongation after canning , TS change due to baking (AB TS)-(H TS) value, YS change due to baking (H YS-AB YS) is out of the range of claim 1 of the present invention Are marked with * in each column of Table 2. A sample satisfying the range described in claim 1 is indicated by a circle in the column of condition 1 in Table 3.
In Table 2, for samples whose (AB TS)-(AB YS) value after baking and the elongation value after canning are out of the most preferred range of the present invention, a square is attached in the column of Table 2. ing. Samples whose conditions are within the most preferable range of the present invention are indicated by ◯ in the column of condition 2 in Table 3.
Samples marked with ○ in the column of Condition 1 in Table 3, that is, samples satisfying the range described in claim 1, have a piercing strength of 46.6 N or more, do not cause rolling cracks, and are broken. The rate is 0 ppm. Moreover, the material proof stress which does not produce the skeleton jam mentioned later satisfies the conditions of 285 Mpa or more.
On the other hand, if any of the conditions of claim 1 is not satisfied, the conditions that do not cause skeleton jam (the material proof stress is 285 MPa or more) are not satisfied (No. 3, 5, 13, 18, 19, 22, 23, 25). Or the piercing strength is 46.5 N or less (No. 4, 5, 13, 18-25), or rolling cracks are likely to occur (No. 8, 9, 14-16), or the rate of occurrence of cylinder breakage. It becomes 10 ppm or more (No. 2, 8, 9, 14-16, 20-22, 24, 25).

When the tensile strength and elongation of the material are high as in the samples No. 20 and No. 24, the barrel breakage tends to occur remarkably. Moreover, all the samples have low puncture strength.
The sample No. 17 has an elongation after canning of less than 5% of the lower limit of the more preferable range, and among samples satisfying the condition 1, the piercing strength is the lowest.
Samples Nos. 1, 6, 7, 10, 11, 12, and 17 shown in Table 1 are samples that satisfy the above-described condition 1.
On the other hand, the sample No. 2 has a material elongation larger than the target range, and is easily cut off. The sample No. 3 had a low material strength and skeleton jam occurred. The No. 4 sample had a low Mg content and was insufficient in terms of piercing strength, and the No. 5 sample had a low Mg content, low piercing strength, and a low material yield strength, resulting in skeleton jam. Samples Nos. 8 and 9 are samples having a high Mg content, but the tensile strength of the material is too high, rolling cracks are generated, and the cylinder is easily cut. The sample No. 13 had a material yield strength after baking of less than 280 MPa, and the yield strength change after baking (H YS) − (AB YS) exceeded 10 MPa, but the piercing strength was low.
The sample No. 14 was a sample with a large amount of (Si + Cu), the sample No. 15 was a sample with a large amount of Cu, and the sample No. 16 was a sample with a large amount of Si.

No. Samples Nos. 18 and 19 have Cu, Mg and Si + Cu below the lower limit, and the material proof strength and post-baking proof strength are less than the lower limits, skeleton jam is likely to occur, and the piercing strength is also low. No. The 19 samples had TS values (AB TS) − (H TS) due to baking and YS values (H YS−AB YS) due to baking outside the scope of claim 1. And the puncture strength is particularly low.
No. When samples Nos. 20 to 23 were subjected to continuous annealing (HOT-CAL) after hot rolling and before cold rolling, no. Samples 24 and 25 are cases where intermediate annealing was not performed, and both were cases where final cold rolling exceeding 70% was performed. These samples are samples with a small amount of Cu, a small amount of Mg, or a small amount of (Si + Cu). However, since the final cold rolling rate is high, the material tensile strength and proof stress exclude No. 22 and 25. And not necessarily low. However, elongation, material strength after baking, TS change due to baking (ABTS)-(HTS) value, YS change due to baking (HYS-ABYS) value, (ABTS)-( Any one of the values of (AB YS) cannot be controlled, the puncture strength cannot be satisfied, and the torso is broken.
Next, in addition to satisfying the above condition 1, the No. 17 sample in which the elongation of the can body after canning was less than 5%, which is a more preferable range, had a tendency to slightly decrease the piercing strength. % Of the samples exhibited excellent puncture strength, and it was found that the can barrel elongation after canning is more preferably 5% or more.

Further, from the results shown in Table 4, when the plate thickness is 0.265 mm and the material yield strength is 285 MPa or more, the moldable speed can be 170 cpm or more, and when the plate thickness is 0.260 mm, the material yield strength is 284 MPa or more, It can be seen that the moldable speed can be 150 cpm or more, and if the sheet thickness is 0.250 mm and the material yield strength is 284 MPa or more, the moldable speed can be 150 cpm or more.
Therefore, if the material yield strength is 285 MPa or more, it can be molded with a plate thickness of 0.265 mm or less and 150 cpm or more, and high production efficiency can be obtained.

  10 ... can body, 11 ... body, 12 ... bottom

Claims (3)

Can body used for manufacturing a can body having a body thickness of 0.096 mm to 0.113 mm, a total drawing ratio of 2.2 to 2.7, and a total ironing ratio of 60% or less Aluminum alloy plate for
In mass%, Mn: 0.8 to 1.1%, Mg: 1.3 to 1.7%, Si: 0.25 to 0.45%, Fe: 0.3 to 0.55%, Cu: 0.25 to 0.45%, Si + Cu: 0.6 to 0.8% , Zn: 0.30% or less, Ti: 0.15% or less , the balance is made of Al containing inevitable impurities,
The plate thickness is 0.240 mm or more and 0.265 mm or less, the material tensile strength is 325 MPa or less, the material proof stress is 285 MPa or more and 310 MPa or less, the material elongation is 2.5% or more and 4.5% or less, The yield strength is 280 MPa or more, the value of (ABTS)-(AB YS) after baking is 35 MPa or more, and the tensile strength of the body portion of the can body after can manufacturing by DI processing and paint baking is 350 MPa or more and 410 MPa or less. And the elongation of the trunk is 4.5% or more,
Resistance to distribution pinhole, characterized in that TS change due to baking (AB TS)-(H TS) is 10 MPa or more and YS change due to baking (H YS-AB YS) is 10 MPa or less. Aluminum alloy plate for can bodies that excels in performance. 2. The intermetallic compound having an equivalent circle diameter of 1 to 10 μm is 3000 / mm ^{2 to} 4800 / mm ² and the area ratio is 1.5 to 2.5%. Aluminum alloy plate for can bodies with excellent distribution pinhole resistance. Used for manufacturing a can body having a body thickness of 0.096 mm to 0.113 mm, a total drawing ratio of 2.2 to 2.7, and a total ironing ratio of 60% or less. To manufacture aluminum alloy sheets for can bodies,
In mass%, Mn: 0.8 to 1.1%, Mg: 1.3 to 1.7%, Si: 0.25 to 0.45%, Fe: 0.3 to 0.55%, Cu: An aluminum alloy casting material containing 0.25 to 0.45%, Si + Cu: 0.6 to 0.8% , Zn: 0.30% or less, Ti: 0.15% or less , and the balance containing inevitable impurities A method for producing an aluminum alloy plate for a can body that is subjected to a hot rolling process and a cold rolling process after homogenization treatment,
Intermediate annealing is performed by heating to a temperature of 450 ° C. or more and 600 ° C. or less for a predetermined time between cold passes,
Then, by performing cold rolling of 50% or more and 70% or less,
The plate thickness is 0.240 mm or more and 0.265 mm or less, the material tensile strength is 325 MPa or less, the material proof stress is 285 MPa or more and 310 MPa or less, the material elongation is 2.5% or more and 4.5% or less, The proof stress is 280 MPa or more, the value of (ABTS)-(AB YS) after baking is 35 MPa or more, and the tensile strength of the body portion of the can body after canning by DI processing and paint baking is 350 MPa or more and 410 MPa or less. And a method for producing an aluminum alloy plate for a can body, wherein the elongation of the body portion is 4.5% or more.

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