JPWO2014129385A1 - Aluminum alloy plate for can body and manufacturing method thereof - Google Patents

Abstract

Mg: 1.0 to 1.5% (mass%, the same applies hereinafter), Mn: 0.8 to 1.2%, Cu: 0.20 to 0.30%, Fe: 0.25 to 0.60% , Si: An aluminum alloy plate for a can body containing 0.20 to 0.40%, the remainder having a chemical component composed of Al and inevitable impurities, and having an electrical conductivity of 37.0 to 40.0% IACS. is there. In addition, the aluminum alloy sheet for can bodies is manufactured through multiple passes of cold rolling, and the tensile strength σB when the material immediately before the final pass of cold rolling is aged at 150 ° C. for 10 hours. (10) and proof stress σ0.2 (10), and tensile strength σB (1) and proof stress σ0.2 (1) when aging treatment is performed at a temperature of 150 ° C. for 1 hour are σB (10) −σB ( 1) ≧ 5 (MPa) and σ0.2 (10) −σ0.2 (1) ≧ 1 (MPa) are satisfied.

Description

  The present invention relates to an aluminum alloy plate for a can body used as a material for a body portion of an aluminum can and a method for producing the same.

  Some can bodies of aluminum beverage cans are formed by subjecting an aluminum alloy plate to DI (Drawing & Ironing) processing. For can bodies formed by DI processing, a 3000 series aluminum alloy having good formability in drawing and ironing is used.

  In recent years, from the viewpoint of reducing the amount of materials used, reducing transportation costs, or cost competitiveness with beverage containers other than aluminum cans, thinner can bodies have been demanded more than ever. In order to achieve thinning of the can body, it is necessary to increase the strength of the aluminum alloy plate as a raw material. As such an aluminum alloy plate, for example, an aluminum alloy plate described in Patent Document 1 has been proposed.

JP 2008-248289 A

  However, the aluminum alloy plate of Patent Document 1 is rolled after being heated again after cooling the ingot after homogenization in the manufacturing process. As described above, in order to increase the strength of a 3000 series aluminum alloy having a conventional component range, it is necessary to perform an additional heat treatment in the manufacturing process, and it is difficult to reduce the manufacturing cost.

  The present invention has been made in view of such a background, and an object of the present invention is to provide an aluminum alloy plate for a can body that has high strength and is easy to manufacture.

In one embodiment of the present invention, Mg: 1.0 to 1.5% (mass%, the same applies hereinafter), Mn: 0.8 to 1.2%, Cu: 0.20 to 0.30%, Fe: 0 .25 to 0.60%, Si: 0.20 to 0.40%, the balance having chemical components consisting of Al and inevitable impurities,
The conductivity is 37.0-40.0% IACS,
And it is manufactured through multiple passes of cold rolling, and the tensile strength σ _{B (10)} and the proof stress σ ₀ when the material immediately before the final pass of the cold rolling is aged at 150 ° C. for 10 hours. _{.2 (10)} and tensile strength σ _{B (1)} and proof stress σ _{0.2 (1)} when aged at 150 ° C. for 1 hour,
σ _{B (10)} −σ _{B (1)} ≧ 5 (MPa), σ _{0.2 (10)} −σ _{0.2 (1)} ≧ 1 (MPa)
The aluminum alloy plate for can bodies is characterized by satisfying the following relationship.

Moreover, other aspects of the present invention include Mg: 1.0 to 1.5% (mass%, the same applies hereinafter), Mn: 0.8 to 1.2%, Cu: 0.20 to 0.30%, A slab containing Fe: 0.25 to 0.60%, Si: 0.20 to 0.40%, the balance having chemical components composed of Al and inevitable impurities,
Chamfering both rolling surfaces and both side surfaces of the slab,
Then, the homogenization process which heats the said slab at 600-620 degreeC for 1 to 24 hours,
After cooling the slab after the homogenization treatment at a cooling rate of 40 ° C./hour or more to 500 to 550 ° C., hot rough rolling is performed,
Next, hot finish rolling is performed so that the outlet temperature is 330 to 360 ° C. to obtain a hot rolled sheet,
Performing either the process of cooling the hot-rolled sheet to 150 ° C. at a cooling rate of 40 ° C./hour or less, or the process of holding the hot-rolled sheet at a temperature of 300 ° C. or higher for 1 hour or longer,
Thereafter, the hot-rolled sheet having a temperature of 80 ° C. or lower is cold-rolled to obtain an intermediate cold-rolled plate having a temperature of 140 ° C. or higher,
Next, the intermediate cold-rolled sheet is held at a temperature of 120 ° C. or more for 2 hours or more,
Then, the final pass of the cold rolling is performed so that the rolling reduction is 48 to 56%, the total rolling reduction of the cold rolling is 87 to 90%, and the temperature is 150 ° C. or higher,
The cold-rolled sheet is cooled to 80 ° C. at a cooling rate of 15 to 30 ° C./hour.

  The aluminum alloy plate for can bodies has the specific chemical component, the conductivity in the specific range, and the aging characteristics in the specific range. Therefore, the aluminum alloy plate for can bodies has a formability equivalent to that of a conventional 3000 series aluminum alloy and has higher strength.

  In addition, by using the above method for producing an aluminum alloy plate for a can body, the aluminum alloy plate for a can body can be produced more easily, and an effect of further reducing the production cost can be expected.

The perspective view of the redraw cup used for bottom wrinkle height measurement in Example 1. FIG. The wrinkle height measurement chart obtained by wrinkle height measurement in Example 1.

  The aluminum alloy plate for can bodies will be described in detail below.

<Mg>
The can body aluminum alloy plate contains 1.0 to 1.5% Mg. Mg dissolves in aluminum and has the effect of improving the strength of the aluminum alloy sheet by solid solution strengthening. Further, the coexistence of Mg, Cu, and Si makes it possible to finely precipitate the compound of Mg, Cu, and Si while the temperature is around 150 ° C. during the cold rolling. The aluminum alloy plate tends to have higher strength due to precipitation strengthening due to these fine precipitates.

  Moreover, the aluminum alloy containing Mg is likely to increase the strength improvement by work hardening in cold working such as cold rolling or DI working. Therefore, the aluminum alloy plate can easily suppress drawing wrinkles and bottom wrinkles in DI processing. Moreover, the can body formed from the aluminum alloy plate is likely to have high strength in terms of can wall strength, that is, can barrel piercing strength and buckling strength.

  The Mg content is 1.0% or more in order to improve the strength of the aluminum alloy plate, and more preferably 1.2% or more. When the Mg content is 1.0% or more, the strength of the aluminum alloy plate is sufficiently high, and the can body can be made thinner more easily. In this case, since work hardening at the time of DI processing is easily increased, it is easy to reduce the occurrence of drawing wrinkles and bottom wrinkles.

  If the Mg content is less than 1.0%, the strength of the aluminum alloy plate may be reduced. In this case, work hardening at the time of DI processing tends to be insufficient, and drawing wrinkles and bottom wrinkles are likely to occur.

  The higher the Mg content, the easier it is to improve the strength of the aluminum alloy plate. However, when the Mg content exceeds 1.5%, the rolling direction when the aluminum alloy plate is pressed into a cup shape is increased. Ears (0-180 ° ears) may become excessively large. Therefore, there is a possibility that a conveyance trouble is likely to occur when the aluminum alloy plate after press working or DI processing is conveyed to the next process.

  In this case, work hardening at the time of cold working may be excessively increased. For this reason, for example, the force applied to the aluminum alloy plate during DI processing may be excessively increased. In some cases, the aluminum alloy plate may break during DI processing or scoring may occur. It is done.

In this case, the amount of Mg that diffuses to the slab surface during the homogenization treatment increases. Therefore, the Mg oxide film formed on the surface of the slab is likely to be thick, and there is a risk of causing a decrease in surface quality such as generation of a flow mark. Furthermore, in this case, since the Mg ₂ Si phase having a large potential difference from the matrix is likely to precipitate, the corrosion resistance of the aluminum alloy plate may be reduced.

  As described above, the content of Mg is 1.0 to 1.5%, and 1.2 to 1.5% is more preferable from the viewpoint of achieving both improvement in strength and improvement in moldability and corrosion resistance. preferable.

<Mn>
The can body aluminum alloy plate contains 0.8 to 1.2% of Mn. Mn dissolves in aluminum and has the effect of increasing the strength of the aluminum alloy sheet by solid solution strengthening. Moreover, Mn has the effect | action which delays recovery | restoration of the process structure produced | generated in the case of cold processing by the heating in a paint baking process etc., and suppresses softening. In addition, Mn coexists with Fe and Si to produce fine crystals of Al ₆ (Mn, Fe) and α-phase compounds (Al—Mn—Fe—Si system). It has the effect of preventing the aluminum alloy plate and the die from seizing.

The Mn content is 0.8% or more and more preferably 1.0% or more in order to easily obtain the strength improvement and seizure prevention effect of the aluminum alloy plate. When the Mn content is 0.8% or more, the strength of the aluminum alloy plate tends to be sufficiently high. Further, in this case, a sufficiently large amount of fine crystals of Al ₆ (Mn, Fe) and α-phase compounds (Al—Mn—Fe—Si system) are generated. It can prevent more reliably that the board and the die are seized.

  If the Mn content is less than 0.8%, the strength of the aluminum alloy plate may be reduced, and the effect of preventing seizure may be reduced.

  The content of Mn is 1.2% or less in order to improve the formability in cold working such as DI working and to easily obtain the effect of delaying recovery after cold working. When the Mn content is 1.2% or less, it becomes easy to sufficiently increase the solid solution amount of Mn in the aluminum alloy. For this reason, the aluminum alloy plate can easily suppress softening by delaying the recovery of the processed structure due to heating in the coating baking process or the like due to the effect of the solid solution Mn.

When the content of Mn exceeds 1.2%, the Al ₆ (Mn, Fe) crystallized product tends to be coarse, and formability in DI processing, necking and flange processing, which are subsequent processes of DI processing, There is a possibility that the moldability in the case is lowered. In this case, since Mn is excessively contained in the aluminum alloy, Mn is easily crystallized or precipitated in the aluminum alloy. When the amount of crystallized matter and precipitates of Mn increases, the amount of solid solution of Mn relatively decreases, so that the effect of delaying recovery after cold working becomes insufficient. Therefore, there is a possibility that the number of recovery sites at the time of empty baking may increase, and in some cases, the strength may decrease during the can making process. Further, it is considered that Si and Fe with a low solid solubility limit are easily crystallized and precipitated as Mn is crystallized and precipitated, which may cause a decrease in strength of the aluminum alloy plate.

  As described above, the content of Mn is 0.8 to 1.2% from the viewpoint of achieving both the strength improvement of the aluminum alloy plate and the formability and softening suppressing effect during cold working, 1.0 to 1.2% is more preferable.

<Cu>
The can body aluminum alloy plate contains 0.20 to 0.30% of Cu. Cu dissolves in aluminum and has the effect of improving the strength of the aluminum alloy sheet by solid solution strengthening. In addition, Cu coexists with Mg, so that Al—Mg—Cu-based fine precipitates are generated while the temperature is around 150 ° C. due to processing heat generated during cold rolling. The aluminum alloy plate tends to have higher strength due to precipitation strengthening due to these fine precipitates. Moreover, Cu has the effect | action which delays recovery | restoration of the process structure | tissue by heating in a paint baking process etc., and suppresses softening.

  The content of Cu is 0.20% or more from the viewpoint of improving the strength of the aluminum alloy plate. In this case, the strength of the aluminum alloy plate can be sufficiently improved by solid solution strengthening or precipitation strengthening.

  If the Cu content is less than 0.20%, the strength improvement effect by precipitation strengthening may be insufficient, and the strength of the aluminum alloy plate may be reduced.

  The higher the Cu content, the easier it is to improve the strength of the aluminum alloy plate. However, if the Cu content exceeds 0.30%, work hardening during cold working may be excessively increased. is there. For this reason, it is necessary to increase the force applied to the aluminum alloy plate during DI processing. In some cases, the aluminum alloy plate may break during DI processing or scoring may occur. Moreover, when content of Cu exceeds 0.30%, there exists a possibility that the corrosion resistance of an aluminum alloy plate may fall.

  As described above, the Cu content is 0.20 to 0.30% from the viewpoint of improving both the strength of the aluminum alloy sheet and the control of work hardening and improving the corrosion resistance.

<Fe>
The said aluminum alloy plate for can bodies contains 0.25-0.60% Fe. Fe coexists with Mn and Si to produce fine crystals of Al ₆ (Mn, Fe) and α-phase compounds (Al—Mn—Fe—Si system), and the above-mentioned aluminum during DI processing. It has the effect of preventing the alloy plate and the die from seizing.

The content of Fe is 0.25% or more and more preferably 0.40% or more in order to easily obtain the effect of preventing seizure and improve the moldability. When Fe is contained in an amount of 0.25% or more, a sufficiently large amount of the above-described fine crystallized Al ₆ (Mn, Fe) or α-phase compound (Al—Mn—Fe—Si system) is generated. Therefore, it is possible to more reliably prevent seizure during DI processing. Moreover, when the intermetallic compound mentioned above is produced | generated, it becomes easy to make the ear | edge (0-180 degree ear | edge) of the rolling direction at the time of pressing the said aluminum alloy plate in a cup shape small. As a result, it becomes easy to reduce troubles when the aluminum alloy plate after press processing or DI processing is conveyed to the next process. Further, when Fe is contained in an amount of 0.25% or more, it becomes easy to suppress the generation of wrinkles in the necking step.

  If the Fe content is less than 0.25%, the effect of preventing seizure may be difficult to obtain. Moreover, in this case, the ears in the rolling direction become excessively large, which may cause troubles during conveyance due to this, and wrinkles may easily occur in the necking process. In addition, when the Fe content is less than 0.25%, it is necessary to use a high-purity metal for the production of the aluminum alloy plate, which may increase the cost.

  Further, the Fe content is 0.60% or less from the viewpoint of controlling the above-described intermetallic compound. When the Fe content exceeds 0.60%, a coarse intermetallic compound is likely to be generated between Mn and Mn. The intermetallic compound is not preferable because it can be a starting point of fracture during molding.

  Thus, the content of Fe is 0.25 to 0.60% in order to satisfy all of moldability, cost, and seizure prevention effect during DI processing, and 0.40% to 0.60%. More preferred.

<Si>
The said aluminum alloy plate for can bodies contains 0.20 to 0.40% Si. Si coexists with Mn and Fe to generate an α-phase compound (Al—Mn—Fe—Si system), and has an effect of preventing the aluminum alloy plate and the die from being seized during DI processing. In addition, Si coexists with Mg and Cu, thereby precipitating a fine intermetallic compound while the temperature is around 150 ° C. during the cold rolling, and strengthening the aluminum alloy plate by precipitation strengthening. Has the effect of improving.

  The Si content is 0.20% or more in order to improve the strength. When Si is contained in an amount of 0.20% or more, a sufficient amount of fine intermetallic compounds with Mg and Cu are precipitated, so that the strength of the aluminum alloy plate is easily improved.

  When the Si content is less than 0.20%, the above-described precipitation of intermetallic compounds may be insufficient, and the strength of the aluminum alloy plate may be reduced. Moreover, in this case, since it is necessary to use a high-purity metal for the production of the aluminum alloy plate, there is a risk of increasing the cost.

  In addition, as the Si content increases, it becomes easier to obtain an effect of preventing seizure, but when it exceeds 0.40%, an Al—Mn—Si phase having a particle size of 0.1 μm or more is likely to precipitate due to Ostwald growth. . In connection with this, there exists a possibility that precipitation of the fine intermetallic compound of Si, Mg, and Cu may become inadequate, and there exists a possibility that the intensity | strength of an aluminum alloy plate may fall. Further, in this case, the solid solution amount of Mn is likely to be lowered, so that the processed structure is likely to be recovered by heating such as baking, and the strength may be lowered during the can manufacturing process.

In addition, when the Si content exceeds 0.40% and the Mg content is higher, coarse crystallized products of the Mg ₂ Si phase may be formed. When this coarse crystallized product is formed, it becomes difficult for the fine intermetallic compound of Si, Mg, and Cu to precipitate. This is not preferable because there is a risk of lowering strength and corrosion resistance. Thus, the Si content is 0.20 to 0.40% in order to satisfy all of the strength, cost, anti-seizure effect and corrosion resistance of the aluminum alloy plate.

<Conductivity>
The aluminum alloy plate for a can body has a conductivity of 37.0 to 40.0% IACS. The electrical conductivity is a measured value used as an indicator of the solid solution amount of Mn, and the lower the electrical conductivity, the greater the solid solution amount of Mn. The aluminum alloy sheet is easy to obtain an effect of improving the strength by solid solution strengthening of Mn by controlling the conductivity obtained by measuring at a temperature condition of 25 ° C. within the above specific range. It becomes easy to obtain the effect of preventing seizure due to precipitation.

  When the electrical conductivity exceeds 40.0% IACS, the solid solution amount of Mn becomes insufficient, so that the strength of the aluminum alloy plate may be lowered. On the other hand, when the conductivity is less than 37.0% IACS, the solid solution amount of Mn increases, so that the strength of the aluminum alloy plate is improved, but the precipitation of the α-phase compound tends to be insufficient, and the seizure prevention effect. May be difficult to obtain.

  The electrical conductivity can be controlled to the above specific range by adjusting, for example, the hot rolling start temperature or the cooling conditions until the hot rolling is started after the homogenization treatment.

Further, when the electrical conductivity is in the specific range, a greater strength improvement effect can be obtained by further controlling the density and size of the Al—Mn—Si based precipitates. That is, it is preferable that the aluminum alloy plate contains 10000 / mm ³ or less of 0.1-2.0 μm Al—Mn—Si based precipitates. The Al—Mn—Si based precipitate has an action of accumulating dislocations during cold working. For this reason, the aluminum alloy plate contains Al—Mn—Si based precipitates controlled to have the specific density and size, so that the strength is easily improved by work hardening.

  When the size of the Al-Mn-Si-based precipitate is less than 0.1 μm, the accumulation of dislocations is less likely to occur during cold rolling and cold working (press work, DI work, etc.), so strength improvement effect Is difficult to obtain. On the other hand, when the size of the Al—Mn—Si based precipitate is larger than 2.0 μm, it becomes difficult to obtain the strength improvement effect because the processed structure is likely to be recovered by heating in the can manufacturing process.

Further, when the density of the Al—Mn—Si based precipitates exceeds 10,000 / mm ³ , the homogenization treatment is not sufficient, and the Al—Mn—Si based precipitates may be segregated. Therefore, it becomes difficult to obtain the anisotropy necessary for controlling the ear rate and the moldability in the can-making process described later. Further, in the case where Al-Mn-Si-based precipitates are segregated, although dislocations are accumulated in the cold working due to the interrelationship of the compounds, a region in which the dislocation-accumulated precipitates are densely arranged and , Sparsely arranged areas will coexist. Therefore, it is considered that the recovery of the processed structure due to heating becomes excessive, and it is difficult to obtain the strength improvement effect.

<Aging characteristics>
Moreover, the said aluminum alloy plate for can bodies has the said specific aging characteristic. The aging characteristic is a value used as an index of the strength improvement effect by precipitation strengthening, and is an index of the strength improvement effect mainly due to precipitation of Al—Cu—Mg-based precipitates. Al-Cu-Mg-based precipitates have a property that it is easy to obtain an effect of improving strength without changing the ear ratio in press working and without adding a process such as heat treatment. Therefore, the productivity of the aluminum alloy plate can be easily improved by using the precipitate.

Tensile strength σ _{B (10)} and proof stress σ _{0.2 (10)} when the material just before the final pass of cold rolling is aged at 150 ° C. for 10 hours, and aged for 1 hour at a temperature of 150 ° C. Tensile strength σ _{B (1)} and proof stress σ _{0.2 (1)} when
σ _{B (10)} −σ _{B (1)} ≧ 5 (MPa), σ _{0.2 (10)} −σ _{0.2 (1)} ≧ 1 (MPa)
When satisfy | filling this relationship, the intensity | strength of the can body manufactured using the said aluminum alloy plate can be improved more with the various precipitates including an Al-Cu-Mg type | system | group precipitate.

  Moreover, it is preferable that the said aluminum alloy plate for can bodies is 300 MPa or more in yield strength in a rolling direction. In this case, various strengths such as can bottom pressure resistance, buckling strength, and can body piercing strength in a can body produced using the aluminum alloy plate can be further improved. As a result, it becomes easy to make the can body obtained thinner by using the aluminum alloy plate.

  Moreover, it is preferable that the aluminum alloy plate for can bodies has a work hardening index of 0.07 or more. The value of work hardening index can be obtained by a tensile test in the rolling direction. When the work hardening index is 0.07 or more, wrinkles (mouth wrinkles during pressing, mouth wrinkles and can bottom wrinkles during DI processing) when manufacturing a can body using the above aluminum alloy plate Occurrence can be further reduced.

  That is, in this case, work hardening in cold working becomes large, so that cold working can be started with a low material strength. The wrinkles generated by cold working are often caused by the material buckling due to the force generated between the material and a processing tool such as a die, and the wrinkle is less likely to occur as the material strength is lower. Therefore, by setting the work hardening index to 0.07 or more, cold working can be performed in a low strength state, and the generation of wrinkles can be further reduced.

Moreover, it is preferable that the ear | edge ratio R calculated from following formula (1) of the shaping | molding cup which carried out the drawing molding on the conditions which made the blank diameter 55mm and a drawing ratio was 1.67 is 4% or less. .
R = (M ₄₅ −V ₄₅ ) / ((M ₄₅ + V ₄₅ ) / 2) × 100 (1)

In the above formula (1), M ₄₅ is a value calculated from the following formula (2), and V ₄₅ is a value calculated from the following formula (3).

M ₄₅ = (A + B + C + D) / 4 (2)

  In the above formula (2), A is 45 ° (angle when the rolling direction is 0 °, the same applies hereinafter), B is 135 ° ear height, and C is 225 ° ear height. Yes, D is 315 ° ear height.

V ₄₅ = (E + F + G + H) / 4 (3)

  In the above formula (3), E is the minimum height of the valley between the 45 ° direction and the 135 ° direction, F is the minimum height of the valley between the 135 ° direction and the 225 ° direction, and G Is the minimum height of the valley between the 225 ° direction and the 315 ° direction, and H is the minimum height of the valley between the 315 ° direction and the 45 ° direction.

  When the ear rate R exceeds 4%, the size of the ear part formed after the aluminum alloy plate is pressed may become excessively large. If the size of the ear part is excessively large, various troubles in the can manufacturing process such as trouble during conveyance, insufficient trimming height after DI processing, or poor tightening due to variations in the flange part in the necking process may occur. It is possible to cause this, which is not preferable.

  Ear ratio R can be controlled by the recrystallization state after hot rolling and the total rolling reduction of cold rolling. When recrystallization after hot rolling is insufficient, the rolling texture tends to remain. In this case, since the rolling texture further grows by subsequent cold rolling, the ear rate R tends to be excessive. Moreover, although the higher one is preferable from a viewpoint of improving the intensity | strength of an aluminum alloy sheet, there is a possibility that the ear rate R may become excessive if the total rolling reduction is excessively increased.

  Next, the manufacturing method of the said aluminum alloy plate for can bodies is explained in full detail. First, an aluminum alloy having the above specific chemical component is cast to produce a slab. As a slab casting method, a known method such as continuous casting or semi-continuous casting can be employed.

  Next, both the rolling surfaces and both side surfaces of the slab are chamfered to remove inhomogeneous portions of the slab surface layer. The thickness of the heterogeneous portion varies depending on the chemical composition of the aluminum alloy, but is usually about 5 mm. If the heterogeneous part remains on the surface of the slab, it is not preferable because the remaining heterogeneous part may cause a reduction in surface quality or ear cracks during rolling.

Then, the homogenization process which heats the said slab at 600-620 degreeC for 1 to 24 hours is performed. By performing the homogenization treatment, additive elements such as Mn, Mg, Si, and Fe that are crystallized or segregated during casting of the slab are dissolved. Further, the Al ₆ (Mn, Fe) crystallized product can be transformed into an α-phase compound (Al—Mn—Fe—Si compound) by homogenization treatment. The α phase compound has a better anti-seizure effect than the Al ₆ (Mn, Fe) crystallized product. Therefore, by performing the homogenization treatment at a temperature in the specific range, the image sticking prevention effect can be further improved. In order to dissolve the additive element and form an α-phase compound, it is preferable to perform the homogenization treatment at a high temperature for a long time.

  When the temperature of the homogenization treatment is less than 600 ° C., the homogenization is performed up to the center of the slab, so that the treatment time becomes long and the productivity tends to decrease. On the other hand, when the temperature of the homogenization treatment exceeds 620 ° C., eutectic melting may occur in a part of the slab, and the quality of the slab surface may be deteriorated. Moreover, when the processing time of the homogenization process is less than 1 hour, the homogenization is not sufficiently performed, and there is a possibility that the strength of the obtained aluminum alloy plate is reduced and the effect of preventing seizure is reduced. The homogenization treatment time is usually 10 hours or less, and the homogenization is sufficiently achieved. Even if the treatment time exceeds 24 hours, it is difficult to obtain an effect commensurate with it.

  After the homogenization treatment, the slab is cooled to 500 to 550 ° C. at a cooling rate of 40 ° C./hour or more, and then hot rough rolling is performed. When the start temperature of hot rough rolling is less than 500 ° C., precipitation of the Al—Mn—Si compound is promoted, so that the solid solution amount of Mn decreases and the strength of the resulting aluminum alloy sheet decreases. There is a fear. On the other hand, when the starting temperature of hot rough rolling exceeds 550 ° C., oxidation of Mg is promoted, so that the surface quality may be deteriorated. In addition, precipitation of the Al—Mn—Si compound occurs also when the high temperature state after the homogenization treatment is continued for a long time. Therefore, the cooling rate is preferably set to 40 ° C./hour or more, and it is more preferable to start cooling as soon as possible after the homogenization treatment. In order to set the cooling rate to 40 ° C./hour or more, cooling means such as water cooling or shower cooling can be employed.

  After hot rough rolling, hot finish rolling is performed so that the delivery temperature is 330 to 360 ° C. to produce a hot rolled sheet. When the exit temperature of hot finish rolling is less than 330 ° C., recrystallization may be insufficient. As a result, when the obtained aluminum alloy plate is pressed, the 45 ° ears may become too large or the ears may be torn off, which may cause a conveyance trouble. Further, in this case, there is a possibility that an ear chip or the like may occur in the trimming process after DI processing, which may cause a decrease in productivity. On the other hand, when the delivery side temperature exceeds 360 ° C., a part of the material being hot rolled may adhere to the rolling roll. For this reason, there is a possibility that the surface quality of the hot-rolled sheet is deteriorated or the appearance is abnormal.

  The hot finish rolling can be performed using, for example, a tandem hot rolling mill having three or more stands. In this case, the rolling reduction in hot finish rolling is preferably 88 to 94%. If the rolling reduction is less than 88%, the amount of strain accumulated during hot finish rolling is small, and recrystallization after the rolling may be insufficient. On the other hand, when the rolling reduction exceeds 94%, a part of the material being hot rolled may adhere to the rolling roll, and the surface quality of the hot rolled sheet may be deteriorated or the appearance may be abnormal.

  Subsequently, either the process which cools a hot-rolled sheet to 150 degreeC with the cooling rate of 40 degrees C / hr or less, or the process which hold | maintains a hot-rolled sheet at the temperature of 300 degreeC or more for 1 hour or more is performed. All of these treatments have the effect of recrystallizing the hot-rolled sheet. That is, regardless of which one of the process of cooling the hot-rolled sheet to 150 ° C. at a cooling rate of 40 ° C./hour or the process of holding the hot-rolled sheet at a temperature of 300 ° C. or higher for 1 hour or longer is selected. The plate can be sufficiently recrystallized, and the ear rate R can be easily controlled to fall within the specific range. If none of the above-described treatments are performed, recrystallization of the hot-rolled sheet becomes insufficient, and there is a risk that it is difficult to control the ear ratio R.

  After performing any of the above-mentioned treatments, the hot-rolled sheet obtained in order to accurately control the temperature during cold rolling is cooled until the temperature becomes 80 ° C. or lower. The cooling rate at this time is not particularly limited. However, if the cooling is excessively slow, it takes time until the next step, which may lead to deterioration in productivity. Therefore, it is desirable to cool using forced cooling means such as fan cooling.

  Thereafter, the hot-rolled sheet having a temperature of 80 ° C. or lower is cold-rolled to produce an intermediate cold-rolled sheet having a temperature of 140 ° C. or higher. Thereby, the said intermediate | middle cold rolled sheet contains the Al-Cu-Mg type compound which precipitates during cold rolling. An Al—Cu—Mg-based compound is a compound that is imparted with work strain due to cold working and starts to precipitate in a state where the temperature is 90 ° C. or higher, and improves the strength of an aluminum alloy plate obtained by precipitation strengthening. Has an effect. Furthermore, since the Al—Cu—Mg-based compound has a property of accumulating processing strain imparted by subsequent cold working, the strength of the obtained aluminum alloy plate can be further improved.

  In order to sufficiently precipitate the Al—Cu—Mg-based compound in the intermediate cold-rolled sheet, it is preferable to set a path during cold rolling so that the temperature of the intermediate cold-rolled sheet is 140 ° C. or higher. When the temperature of the intermediate cold-rolled plate is 140 ° C. or higher, an Al—Cu—Mg compound can be precipitated. When the temperature of the intermediate cold-rolled plate exceeds 170 ° C., there is a possibility that recovery of the processed structure that leads to a decrease in strength occurs.

  Next, by holding the obtained intermediate cold-rolled plate at a temperature of 120 ° C. or more for 2 hours or more, the Al—Cu—Mg-based compound can be sufficiently aged in the intermediate cold-rolled plate. When the time for holding the intermediate cold-rolled sheet at 120 ° C. or more exceeds 10 hours, it is over-aged, and the strength of the resulting aluminum alloy sheet may be reduced, and the productivity may be reduced. Absent.

  Thereafter, the final pass of the cold rolling is performed on the obtained intermediate cold-rolled sheet so that the reduction ratio is 48 to 56%. Thereby, the cold rolling sheet whose total rolling reduction of cold rolling is 87 to 90% and temperature is 150 degreeC or more is obtained. By setting the temperature of the cold-rolled sheet to 150 ° C. or higher, the processing strain of the obtained aluminum alloy sheet can be recovered moderately, and the formability in the subsequent press working or DI working can be improved. Although there is no upper limit to the temperature of the cold-rolled sheet obtained, there is no problem in product characteristics up to at least 190 ° C., and the formability is further improved.

  Moreover, by making the total rolling reduction ratio of the cold-rolled sheet in the cold rolling within the specific range, work hardening can be sufficiently increased, and the strength of the aluminum alloy sheet can be improved. When the total rolling reduction is less than 87%, work hardening becomes insufficient, and the strength of the resulting aluminum alloy plate may be reduced. On the other hand, when the total rolling reduction exceeds 90%, the ear rate R may increase, which is not preferable.

  The cold-rolled sheet can control the temperature after the final pass by the temperature of the intermediate cold-rolled plate and the rolling reduction in the final pass of cold rolling. That is, when the rolling reduction is less than 48%, the processing heat generation becomes small, so the temperature of the cold-rolled sheet may be less than 150 ° C. On the other hand, when the rolling reduction exceeds 56%, the strain on the rolled surface after rolling becomes excessively large, resulting in the occurrence of sheet breakage, the occurrence of oil coating unevenness, or the plate passing during cup molding in the can manufacturing process. It may cause problems such as being caught.

  Thus, the rolling reduction in the final pass of cold rolling is 48 to 56% in order to satisfy both the control of the temperature of the cold-rolled sheet and the reduction of the rolling surface strain, and 50 to 54%. More preferred.

  Then, the said aluminum sheet for can bodies can be obtained by cooling the said cold rolled sheet to 80 degreeC with the cooling rate of 15-30 degreeC / hour. By cooling the cold-rolled plate under the above-described conditions, the Al—Cu—Mg-based compound can be aged and the work hardening of the aluminum alloy plate can be further increased. Further, in this case, since the recovery of the processed structure occurs, the moldability in the subsequent can manufacturing process can be further improved. When the cooling rate is less than 15 ° C./hour, the recovery of the processed structure tends to be excessive, and the resulting aluminum alloy sheet may be deteriorated in strength due to overaging. On the other hand, when the cooling rate exceeds 30 ° C./hour, the recovery of the processed structure tends to be insufficient, and the moldability may be reduced.

  It is preferable that the said aluminum alloy plate for can bodies manufactured by the above method is supplied to a can manufacturing process, without performing tension correction. As described above, the can body aluminum alloy plate has a large work hardening that occurs during cold working due to the action of an Al—Cu—Mg compound or the like. Therefore, by performing tension correction before being supplied to the can manufacturing process, the strength of the material supplied to the press process or DI process may increase unintentionally, and wrinkles are likely to occur in these processes. There is.

Example 1
Examples of the aluminum alloy plate for can bodies will be described below.

<Slab production>
First, slabs were produced by DC casting using aluminum alloys (alloys No. 1 to No. 9) containing chemical components shown in Table 1. Next, both rolled surfaces of the slab were chamfered by 10 mm, and both side surfaces were chamfered by 5 mm. Thereafter, the slab was heated at 605 ° C. for 2 hours for homogenization. After the homogenization treatment, the slab was cooled to 515 ° C. at a cooling rate of 45 ° C./hour, and this temperature was maintained for 2 hours to make the temperature of the entire slab uniform.

<Hot rolling>
Next, the hot rough rolling of the slab is started from a state where the temperature of the slab is 515 ° C. using a reverse rolling mill, and the hot rough rolling is performed in a state where the plate thickness is set to 30 mm by a plurality of rolling passes. Completed. The temperature of the slab when hot rough rolling was completed was 465 ° C. After hot rough rolling, hot finish rolling was performed at a reduction rate of 92% using a 4-tandem hot finish rolling mill, thereby producing a hot rolled sheet having a thickness of 2.4 mm. The exit temperature of the hot-rolled sheet was 340 ° C.

<Cold rolling>
The hot-rolled sheet obtained as described above was cooled to 150 ° C. at a cooling rate of 25 ° C./hour, and further cooled to 55 ° C. by fan cooling. Then, the cold rolling of 2 passes using a single rolling mill was performed, and the intermediate cold rolled sheet was obtained. The thickness of the obtained intermediate cold-rolled plate was 0.58 mm, and the temperature was 155 ° C.

  Next, the intermediate cold-rolled plate was held at a temperature of 120 ° C. or higher for 140 minutes. Thereafter, using a single rolling mill, from the state where the temperature of the intermediate cold-rolled sheet was 118 ° C., the final pass of the cold rolling was performed with a reduction rate of 53.4% to obtain a cold-rolled sheet. The obtained cold-rolled sheet had a thickness of 0.27 mm and a temperature of 165 ° C. The total rolling reduction in cold rolling was 88.8%.

<Finish>
Thereafter, the cold-rolled sheet was cooled to 80 ° C. at a cooling rate of 22 ° C./hour, washed with rolling oil and applied with re-oil oil without performing tension correction, and the aluminum alloy plates shown in Tables 2 and 3 ( Test materials No. 1 to No. 9) were obtained. In addition, application | coating of lioil oil was performed by electrostatic application, and the application quantity was 100 mg / m < ² >.

Table 2 shows the results of conducting conductivity measurements and evaluating aging characteristics for each test material obtained as described above. In addition, the value of the tensile strength and proof stress of the rolling direction measured based on JISZ2241 was used for evaluation of an aging characteristic. Specifically, a material (intermediate cold-rolled sheet) immediately before the final pass of cold rolling is sampled and tensile strength σ _{B (10)} and proof stress σ ₀ when aging treatment is performed at a temperature of 150 ° C. for 10 hours. _{.2 (10)} was measured. Similarly, the material immediately before the final pass of the cold rolling was collected, and the tensile strength σ _{B (1)} and the proof stress σ _{0.2 (1)} when the material was aged at 150 ° C. for 1 hour were measured. . Then, the difference between σ _{B (10)} and σ _{B (1)} and the difference between σ _{0.2 (10)} and σ _{0.2 (1)} were calculated. Conductivity measurement was performed using a conductivity meter (“Sigma Test 2.069” manufactured by Forster Co., Ltd.), and the temperature of the test material during measurement was 25 ° C.

  Table 3 shows the mechanical properties and the ear ratio R of each test material evaluated by the following method.

<Mechanical properties>
A tensile test in the rolling direction was performed in accordance with JIS Z2241, and the tensile strength σ _B and proof stress σ _0.2 of each test material were measured. The value of proof stress σ _0.2 is preferably 300 MPa or more. Test materials with a proof stress σ _0.2 of less than 300 MPa are shown underlined in Table 3.

  Further, a work hardening index (n value) was calculated from the tensile test result. The n value is preferably 0.07 or more. Samples with an n value of less than 0.07 are underlined in Table 3.

<Ear rate R>
A 55 mm diameter blank was taken from each test material, and was drawn into a cup shape under the conditions of a drawing ratio of 1.67. The ear ratio R of this cup was calculated using the above formulas (1) to (3). The ear rate R is preferably 4% or less. The test materials with the ear rate R exceeding 4% are underlined in Table 3.

  Next, a DI can was molded from each test material, and baked at 205 ° C. for 10 minutes to prepare a can-shaped test body. Table 3 shows the results of evaluation of can bottom pressure resistance, DI moldability, and flange moldability by the following methods using this test specimen.

<Can bottom pressure resistance>
The can bottom shape of the test specimen (DI can) was 48 mm and the dome depth was 9.8 mm, and the can bottom pressure resistance was measured. The bottom pressure resistance of the can is preferably 600 kPa or more. The test materials with a can bottom pressure of less than 600 kPa are underlined in Table 3.

<DI moldability>
100 cans were made for each of the test specimens aiming at a wall thickness of 0.105 mm, and the can production success rate and the appearance were evaluated by visual observation. In Table 3, ◎ is a symbol indicating that all cans (100 cans) have been successfully molded and there is no appearance defect, and ○ indicates that all cans (100 cans) have been successfully molded but appearance defects have occurred. Is a symbol indicating that 1 to 5 cans have been broken, and x is a symbol indicating that 6 or more cans have been broken. The DI moldability is preferably that all cans have been successfully molded and there is no appearance defect (indicated by ◎). The test materials in which appearance defects occurred (indicated by ◯) or fractures occurred (indicated by Δ and ×) are shown underlined in Table 3.

<Flange formability>
After 100 cans of each of the test specimens were formed, the ears were trimmed, and smooth die necking was performed up to 204 diameters. Thereafter, a flange having a flange thickness of 157 μm and a flange width of 2.4 mm was formed at the opening end, and the presence or absence of cracks at the flange end was evaluated by visual observation. In Table 3, “◯” indicates that all cans (100 cans) have succeeded and no flange cracks occur, and “×” indicates that one or more cans have flange cracks. As for the flange formability, it is preferable that all cans have been successfully formed and there is no flange cracking (indicated by a circle). The test material in which flange cracking occurred (indicated by x) is shown underlined in Table 3.

  Next, five cans of redraw cups 1 (without dome molding) in the process of DI shown in FIG. 1 were prepared from each test material. Table 3 shows the results of evaluating the bottom wrinkle height using the redraw cup 1 by the following method.

<Bottom wrinkle height>
As shown in FIG. 1, the wrinkle 12 of the chime portion 11 in each redraw cup 1 is measured using a roundness meter 2 (manufactured by Mitutoyo Corporation, model EC-1010A) to obtain a wrinkle height measurement chart. It was. An example of a wrinkle height measurement chart is shown in FIG. This chart is a circular coordinate centered on the point O, and has an angle in the circumferential direction and wrinkles 12 in the radial direction. In the obtained chart, for the adjacent peaks 3 and valleys 4, calculated by (the value of the distance 31 from the point O to the peak of the peak 3 −the value of the distance 41 from the point O to the peak of the valley 4). The value to be obtained was defined as the wrinkle height H. The wrinkle is calculated for each of the ridges 3 in the entire circumference of the height H chime unit 11, and of which the largest value as the maximum wrinkle height H _max. Then, an average value of maximum wrinkle height H _max calculated for each of the five cans made from the same test material are shown in Table 3 this value as the bottom wrinkle height H _b. The bottom wrinkle height _Hb is preferably 200 μm or less. The specimens with the bottom wrinkle height _Hb exceeding 200 μm are underlined in Table 3.

  As known from Table 1, the test material No. 1-No. 3 is formed from an alloy (alloys No. 1 to No. 3) having the specific chemical component. Further, as known from Table 2, the test material No. 1-No. 3 indicates the conductivity in the specific range, and has the specific aging characteristic. Therefore, test material No. 1-No. 3 is excellent in mechanical properties and moldability, as well as in product properties of a test specimen prepared using the sample, as is known from Table 3. On the other hand, test material No. 4-No. No. 9 was inferior in mechanical properties and the like as shown in Table 3 because at least one additive element of the chemical component was outside the above-mentioned specific range as shown in Table 1.

(Example 2)
This example shows the alloy No. 1 in Example 1. This is an example in which the slab was produced using No. 1 and then the production conditions were variously changed to produce the aluminum alloy plate for a can body. That is, in this example, each process of slab production, hot rolling, cold rolling and finishing is performed using various manufacturing conditions (manufacturing conditions A to M) shown in Table 4 instead of the manufacturing conditions of Example 1. It carried out sequentially and produced the aluminum alloy plate (test material No. 11-23) shown in Table 5 and Table 6.

  Table 5 shows the results of conducting the electrical conductivity measurement and the aging characteristic evaluation of each test material by the same method as in Example 1.

  Table 6 shows the results of evaluating the mechanical characteristics and the like of each test material by the same method as in Example 1.

  Test material No. 11-No. The manufacturing conditions (manufacturing conditions A to C) adopted in No. 13 are included in the specific range. Further, as known from Table 5, the test material No. 11-No. Reference numeral 13 denotes the conductivity in the specific range, and has the specific aging characteristic. Therefore, test material No. 11-No. No. 13, as is known from Table 6, is excellent in mechanical properties and moldability, and also excellent in product characteristics of a test specimen prepared using the test material.

  Moreover, according to the manufacturing method of this example, after performing a homogenization process to a slab, the said aluminum alloy plate for can bodies can be manufactured, without performing an additional heat processing process. Therefore, the aluminum alloy plate for can bodies can be manufactured more easily, and the effect of reducing the manufacturing cost can be expected.

  Test material No. No. 14 was produced using the production conditions included in the above specific range, but since the tensile correction was performed, work hardening occurred and the moldability was poor. This is considered to be because the correction force in tension correction was too large, and it is estimated that the moldability can be improved by adjusting the correction force.

  Test material No. 15-No. No. 23, as shown in Table 4, at least one of the items in the manufacturing conditions is out of the above specific range, so that the mechanical characteristics and the like are inferior as shown in Table 6.

(Example 3)
This example is an example of an aluminum alloy sheet prepared by performing heat treatment on the obtained hot-rolled sheet after hot finish rolling in Example 2. The manufacturing method in this example will be described below.

<Slab production>
First, alloy no. 1 was used to produce a slab by DC casting. Next, both rolled surfaces of the slab were chamfered by 10 mm, and both side surfaces were chamfered by 5 mm. Thereafter, the slab was heated at 605 ° C. for 2 hours for homogenization. After the homogenization treatment, the slab was cooled to 530 ° C. at a cooling rate of 45 ° C./hour, and this temperature was maintained for 2 hours to make the temperature of the entire slab uniform.

<Hot rolling>
Next, the hot rough rolling of the slab is started from a state where the temperature of the slab is 530 ° C. using a reverse rolling mill, and the hot rough rolling is performed in a state where the plate thickness is set to 30 mm by a plurality of rolling passes. Completed. The temperature of the slab when hot rough rolling was completed was 465 ° C. After hot rough rolling, hot finish rolling was performed using a 4-tandem hot finish rolling mill with a reduction rate of 91.3%. Thereby, a hot-rolled sheet having a thickness of 2.6 mm was produced. The exit side temperature of the hot-rolled sheet was 335 ° C.

<Heat treatment before cold rolling>
The hot-rolled sheet obtained as described above was heat-treated at a temperature of 330 ° C. for 2 hours, and then cooled to 75 ° C. by fan cooling. Then, the cold rolling of 2 passes using a single rolling mill was performed, and the intermediate cold rolled sheet was obtained. The thickness of the obtained intermediate cold-rolled sheet was 0.58 mm, and the temperature was 160 ° C.

  Next, the intermediate cold-rolled plate was held at a temperature of 120 ° C. or higher for 4.8 hours. Then, using a single rolling mill, the final pass of cold rolling was performed at a reduction rate of 53.4%, to obtain a cold rolled sheet. The obtained cold-rolled sheet had a thickness of 0.27 mm and a temperature of 172 ° C. The total rolling reduction in cold rolling was 89.6%.

<Finish>
Thereafter, the cold-rolled sheet was cooled to 80 ° C. at a cooling rate of 24 ° C./hour, washed with rolling oil and applied with reoil oil without performing tension correction, and the aluminum alloy plates shown in Tables 7 and 8 ( Test material No. 24) was obtained. In addition, application | coating of lioil oil was performed by electrostatic application, and the application quantity was 100 mg / m < ² >.

  In the same manner as in Example 1, the test material No. Table 7 shows the results of 24 electrical conductivity measurements and evaluation of aging characteristics.

  In the same manner as in Example 1, the test material No. Table 8 shows the results of evaluating 24 mechanical properties and the like.

  As is known from Tables 7 and 8, the hot-rolled sheet after hot rolling is subjected to a heat treatment that is held at 300 ° C. or higher for 1 hour or longer to cool the hot-rolled sheet at a cooling rate of 40 ° C./hour or lower. As in the case of cooling to 150 ° C., a test material excellent in mechanical properties and moldability can be obtained. Moreover, the product characteristic of the test body produced using the test material is excellent.

  In addition, you may perform the heat processing of 300 degreeC or more and 1 hour or more shown in this example at any time after hot rolling and before cold rolling. That is, for example, after the hot-rolled sheet is cooled at a cooling rate exceeding 40 ° C./hour, the hot-rolled sheet may be heated again to perform the heat treatment, or immediately after the hot-rolled sheet is manufactured, the heat treatment may be performed. Good.

Claims (5)

Mg: 1.0 to 1.5% (mass%, the same applies hereinafter), Mn: 0.8 to 1.2%, Cu: 0.20 to 0.30%, Fe: 0.25 to 0.60% Si: 0.20 to 0.40%, with the remainder having chemical components consisting of Al and inevitable impurities,
The conductivity is 37.0-40.0% IACS,
And it is manufactured through multiple passes of cold rolling, and the tensile strength σ _{B (10)} and the proof stress σ ₀ when the material immediately before the final pass of the cold rolling is aged at 150 ° C. for 10 hours. _{.2 (10)} and tensile strength σ _{B (1)} and proof stress σ _{0.2 (1)} when aged at 150 ° C. for 1 hour,
σ _{B (10)} −σ _{B (1)} ≧ 5 (MPa), σ _{0.2 (10)} −σ _{0.2 (1)} ≧ 1 (MPa)
An aluminum alloy plate for a can body characterized by satisfying the relationship of   The aluminum alloy plate for can bodies according to claim 1, wherein the proof stress in the rolling direction is 300 MPa or more.   The aluminum alloy plate for can bodies according to claim 1 or 2, wherein the work hardening index is 0.07 or more. The aluminum alloy plate for a can body according to any one of claims 1 to 3, wherein the blank cup has a diameter of 55 mm and a drawing cup formed by drawing under the condition that the drawing ratio is 1.67. The aluminum alloy plate for a can body, wherein the ear rate R calculated from (1) is 4% or less.
R = (M ₄₅ −V ₄₅ ) / ((M ₄₅ + V ₄₅ ) / 2) × 100 (1)
(In the above formula (1), M ₄₅ is a value calculated from the following formula (2), and V ₄₅ is a value calculated from the following formula (3).
M ₄₅ = (A + B + C + D) / 4 (2)
In the above formula (2), A is 45 ° (angle when the rolling direction is 0 °, the same applies hereinafter), B is 135 ° ear height, and C is 225 ° ear height. Yes, D is 315 ° ear height.
V ₄₅ = (E + F + G + H) / 4 (3)
In the above formula (3), E is the minimum height of the valley between the 45 ° direction and the 135 ° direction, F is the minimum height of the valley between the 135 ° direction and the 225 ° direction, and G Is the minimum height of the valley between the 225 ° direction and the 315 ° direction, and H is the minimum height of the valley between the 315 ° direction and the 45 ° direction. ) Mg: 1.0 to 1.5% (mass%, the same applies hereinafter), Mn: 0.8 to 1.2%, Cu: 0.20 to 0.30%, Fe: 0.25 to 0.60% , Si: 0.20-0.40% is contained, and the slab having a chemical component consisting of Al and inevitable impurities is produced.
Chamfering both rolling surfaces and both side surfaces of the slab,
Then, the homogenization process which heats the said slab at 600-620 degreeC for 1 to 24 hours,
After cooling the slab after the homogenization treatment at a cooling rate of 40 ° C./hour or more to 500 to 550 ° C., hot rough rolling is performed,
Next, hot finish rolling is performed so that the outlet temperature is 330 to 360 ° C. to obtain a hot rolled sheet,
Performing either the process of cooling the hot-rolled sheet to 150 ° C. at a cooling rate of 40 ° C./hour or less, or the process of holding the hot-rolled sheet at a temperature of 300 ° C. or higher for 1 hour or longer,
Thereafter, the hot-rolled sheet having a temperature of 80 ° C. or lower is cold-rolled to obtain an intermediate cold-rolled plate having a temperature of 140 ° C. or higher,
Next, the intermediate cold-rolled sheet is held at a temperature of 120 ° C. or more for 2 hours or more,
Then, the final pass of the cold rolling is performed so that the rolling reduction is 48 to 56%, the total rolling reduction of the cold rolling is 87 to 90%, and the temperature is 150 ° C. or higher,
A method for producing an aluminum alloy plate for a can body, wherein the cold-rolled plate is cooled to 80 ° C at a cooling rate of 15 to 30 ° C / hour.

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