EP2426227A1 - Aluminum alloy sheet forlithographic printing plate, and manufacturing method thereof - Google Patents

Aluminum alloy sheet forlithographic printing plate, and manufacturing method thereof Download PDF

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Publication number
EP2426227A1
EP2426227A1 EP11179125A EP11179125A EP2426227A1 EP 2426227 A1 EP2426227 A1 EP 2426227A1 EP 11179125 A EP11179125 A EP 11179125A EP 11179125 A EP11179125 A EP 11179125A EP 2426227 A1 EP2426227 A1 EP 2426227A1
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EP
European Patent Office
Prior art keywords
aluminum alloy
aluminum
alloy sheet
molten metal
mass
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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Application number
EP11179125A
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German (de)
English (en)
French (fr)
Inventor
Yusuke Namba
Shinya Kurokawa
Hirokazu Sawada
Akio Uesugi
Hirotake Osuga
Yoshikazu Suzuki
Kotaro Kitawaki
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Fujifilm Corp
UACJ Corp
Original Assignee
Furukawa Sky Aluminum Corp
Fujifilm Corp
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Application filed by Furukawa Sky Aluminum Corp, Fujifilm Corp filed Critical Furukawa Sky Aluminum Corp
Publication of EP2426227A1 publication Critical patent/EP2426227A1/en
Withdrawn legal-status Critical Current

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Classifications

    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C21/00Alloys based on aluminium
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41NPRINTING PLATES OR FOILS; MATERIALS FOR SURFACES USED IN PRINTING MACHINES FOR PRINTING, INKING, DAMPING, OR THE LIKE; PREPARING SUCH SURFACES FOR USE AND CONSERVING THEM
    • B41N1/00Printing plates or foils; Materials therefor
    • B41N1/04Printing plates or foils; Materials therefor metallic
    • B41N1/08Printing plates or foils; Materials therefor metallic for lithographic printing
    • B41N1/083Printing plates or foils; Materials therefor metallic for lithographic printing made of aluminium or aluminium alloys or having such surface layers
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B21/00Obtaining aluminium
    • C22B21/06Obtaining aluminium refining
    • C22B21/062Obtaining aluminium refining using salt or fluxing agents
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B21/00Obtaining aluminium
    • C22B21/06Obtaining aluminium refining
    • C22B21/064Obtaining aluminium refining using inert or reactive gases
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22BPRODUCTION AND REFINING OF METALS; PRETREATMENT OF RAW MATERIALS
    • C22B21/00Obtaining aluminium
    • C22B21/06Obtaining aluminium refining
    • C22B21/066Treatment of circulating aluminium, e.g. by filtration
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C1/00Making non-ferrous alloys
    • C22C1/02Making non-ferrous alloys by melting
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C1/00Making non-ferrous alloys
    • C22C1/02Making non-ferrous alloys by melting
    • C22C1/026Alloys based on aluminium
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22FCHANGING THE PHYSICAL STRUCTURE OF NON-FERROUS METALS AND NON-FERROUS ALLOYS
    • C22F1/00Changing the physical structure of non-ferrous metals or alloys by heat treatment or by hot or cold working
    • C22F1/04Changing the physical structure of non-ferrous metals or alloys by heat treatment or by hot or cold working of aluminium or alloys based thereon

Definitions

  • the present invention relates to an aluminum alloy sheet used for a lithographic printing plate formed by anodizing a surface of an aluminum alloy sheet subjected to a roughening treatment and by coating it with a photosensitive substance, and a method of manufacturing the aluminum alloy sheet. More specifically, the present invention relates to an aluminum alloy sheet for a lithographic printing plate which is excellent in the pit uniformity after a roughening treatment, the ink stain resistance in a non-image area and the fault tolerance of a photosensitive layer after prolonged storage, and a method of manufacturing the excellent aluminum alloy sheet.
  • a lithographic printing plate In general, as a lithographic printing plate, is used a support which is obtained by subjecting a surface of an aluminum sheet or an aluminum alloy sheet to surface treatments such as a roughening treatment, an anodized film treatment, etc., and which is coated with a photosensitive substance.
  • a so-called PS (Pre-Sensitized) plate comprising a support previously coated with the photosensitive substance is widely used, and thus it can be immediately subjected to an exposing processing.
  • An image forming area on the lithographic printing plate is formed as a lipophilic image forming area for receiving an ink, which is defined by a part of the photosensitive layer which is not dissolved in the development processing.
  • a non-image area on the lithographic printing plate as a hydrophilic non-image area for receiving a fountain solution, from which a part of the photosensitive layer is dissolved and removed in the development processing so that an anodized layer is exposed therefrom.
  • the printing plate fabricated as above is wound around a rotatable plate cylinder of a printing machine. Then, the ink is applied to the image forming area on the wound lithographic printing plate under the presence of the fountain solution.
  • the image formed on the printing plate by the ink is transferred to a rubber blanket, and is then printed on a printing medium.
  • aluminum alloys such as JIS1050, JIS1100, JIS3003, etc. have been used for an aluminum alloy sheet for the lithographic printing plate.
  • the aluminum alloy sheet is usually roughened by roughening treatments by one or a combination of two or more of a mechanical method, a chemical method and an electrochemical method.
  • the sheet is then subjected to an anodization treatment and a hydrophilic treatment, if necessary, and is used as a support for the lithographic printing plate.
  • a photosensitive coat is applied to a surface of the support for the lithographic printing plate.
  • the original printing plate is obtained by subjecting the support to an exposure processing and a development processing.
  • the photosensitive layer of the CTP-type lithographic printing plate is more sensitive to light and heat than the prior-art lithographic printing plates.
  • an intermetallic compound on the surface of the aluminum alloy sheet, a defect can easily occur in the photosensitive layer.
  • intermetallic compounds such as the single Si and coarse Ti-B-based compounds cause ink stains.
  • the single Si refers to those not forming a solid solution in the alloy but separated as Si grains in Si contained in the aluminum alloy.
  • Patent Document 1 describes that since a defect occurs in an anodized film by the single Si, which lowers a hydrophilic property in that portion and causes ink stains, a reduction of the single Si in the aluminum alloy sheet is effective.
  • Patent Document 2 describes that by adjusting contents of Mg and Mn so as to be separated as Mg2Si or Al-Mn-Si based compounds, a separation of the single Si can be suppressed.
  • Patent Document 3 describes a method of continuously casting an aluminum support after removing a coarse Ti-B compound from an aluminum molten metal through a filter.
  • Patent Document 4 describes that, in a continuous casting method including a process where an aluminum molten metal is successively passed through a filtering means, molten metal flow passages, liquid level control means, and a molten metal feed nozzle, trap means for separated grains containing the Ti-B compound present in the molten metal is provided at one or more spots in the liquid level control means and the molten metal feed nozzle, and that time during which the molten metal passes through the molten metal flow passages and a distance of the molten metal flow passages are regulated.
  • the removal of the Ti-B aggregation substances is not sufficient, and infusion of coarse aggregation substances cannot be stably prevented.
  • ink stains cannot be sufficiently solved even by regulating the inclusion such as the intermetallic compounds.
  • Patent Document 5 describes that an inert gas is blown into a molten metal after an electrolytic refining of an aluminum oxide, a holding time in a holding process is regulated, and a filtration is performed by an in-line degassing treatment and an in-line filter so as to control the aluminum carbide concentration contained in an aluminum alloy sheet manufactured from the molten metal.
  • Patent Document 6 describes that amounts of oxides and carbides are controlled by performing at least one of a melting process, a holding process, a hydrogen-gas removing process, a filtering process and a casting process in a protective gas atmosphere containing a fluoride gas.
  • Patent Documents 5 and 6 an effect to decrease the aluminum carbide amount is not sufficient, and it is difficult to stably manufacture an aluminum alloy sheet in which the aluminum carbide amount is decreased. Also, an aluminum fluoride indicated in Patent Document 5 and an aluminum fluoride generated by the reaction between the protective gas containing a fluoride gas and the molten metal described in Patent Document 6 are likely to generate a hydrogen fluoride by heating in the the atmosphere. Since the hydrogen fluoride has the extremely strong toxicity to biological bodies and severe corrosiveness, they have problems of a bad influence on human bodies and a damage of a furnace.
  • An object of the present invention is to provide an aluminum alloy for a lithographic printing plate which is excellent in the pit uniformity after a roughening treatment, the ink stain resistance in a non-image area and the fault tolerance of a photosensitive layer after prolonged storage by decreasing an amount of an aluminum carbide and preventing an aggregation of at least one of a Ti-B compound and a Ti-C compound and the aluminum carbide.
  • the inventors have found that the object can be achieved by strictly controlling conditions in a melting process stage of an aluminum alloy and in a treating process stage of a molten metal, and completed the present invention.
  • an aluminum alloy sheet for a lithographic printing plate contains 0.10 to 0.60 mass% Fe, 0.01 to 0.25 mass% Si, 0.0001 to 0.05 mass% Cu, 0.005 to 0.05 mass% Ti, 0.0001 to 0.0020 mass% of one or more types selected from B and C, the balance of Al, and unavoidable impurities; wherein the concentration of an aluminum carbide present in the aluminum alloy sheet is not more than 8 ppm; and wherein when an area occupancy ratio of aggregation substances present on a surface of the aluminum alloy sheet subjected to a roughening treatment to a circle area with a radius of 5 ⁇ m arbitrarily set on the surface of the aluminum alloy sheet is less than 10%, the aggregation substances comprising at least one of a Ti-B compound and a Ti-C compound, and the aluminum carbide. In the case where the area occupancy ratio of the aggregation substances is not less than 10%, the aggregation substances are present at a rate of 1 to 2 pieces/50
  • a method of manufacturing an aluminum alloy sheet for a lithographic printing plate comprises the steps of:
  • the aluminum alloy sheet for a lithographic printing plate according to the present invention is excellent in the pit uniformity after a roughening treatment, with less ink stains occurred in a non-image area during printing, that is, excellent in the ink stain resistance and moreover, less faults of the photosensitive layer occurred in a photosensitive layer if stored under the atmosphere, that is, excellent in the fault tolerance of the photosensitive layer after long-term storage. Also, with the manufacturing method of an aluminum alloy sheet for a lithographic printing plate according to the present invention, the above aluminum alloy sheet for a lithographic printing plate can be obtained reliably and stably.
  • the Fe content affects sizes and number densities of Al-Fe-based compounds and Al-Fe-Si-based compounds dispersed in the material, and also largely affects the crystal grain behaviors during re-crystallization and the pit uniformity generated during a roughening treatment.
  • % 0.10 mass%
  • the crystal grain size at re-crystallization is coarsened and the pits generated by the roughening treatment become non-uniform.
  • the Fe content exceeds 0.60%, coarse Al-Fe-based compounds and Al-Fe-Si-based compounds are increased, and the pits generated by the roughening treatment become non-uniform.
  • the Fe content should be within a range of 0.10 to 0.60%.
  • the preferable Fe content is within the range of 0.20 to 0.40%.
  • the Si content When the Si content is less than 0.01%, after a roughening treatment, the pits become non-uniform. On the other hand, if the Si amount exceeds 0.25%, coarse Al-Fe-Si-based compounds are increased, and pits become non-uniform after the roughening treatment. Also, a separation of the single Si can easily occur, which remains in the anodized film and causes film defects. As a result, these defects become starting points of stains in the non-image area during printing, and cause stains in printing. Thus, the Si content should be within a range of 0.01 to 0.25%. The preferable Si content is within the range of 0.07 to 0.15%.
  • Cu is an element which largely affects the roughening properties.
  • the Cu content is less than 0.0001%, pits generated by a roughening treatment become non-uniform.
  • the Cu content exceeds 0.05%, the pits generated by the roughening treatment also become non-uniform, and the color tone of the surface becomes too black, which damages merchantability.
  • the Cu content should be within a range of 0.0001 to 0.05%.
  • the preferable Cu content is within the range of 0.005 to 0.04%.
  • Ti is an element which largely affects roughening properties, and also is an element which largely affects a structural state of an aluminum alloy ingot.
  • the Ti content is less than 0.005%, after an roughening treatment, the pits become non-uniform. Also, crystal grains of the ingot are not refined, but become coarse crystal grain structures, and band-shaped stripes are generated along the rolling direction, and the band-shaped stripes remain even after the roughening treatment.
  • the Ti content exceeds 0.05%, not only the above-described effects are saturated, but also coarse Al-Ti-based compounds are formed, and the compounds are distributed in the stripe shape on a rolled plate.
  • the Ti content should be within a range of 0.005 to 0.05%,
  • the preferable Ti content is within the range of 0.005 to 0.03%.
  • the aluminum carbide can be easily separated at a spot where the Ti-B-based compounds and the Ti-C-based compounds are present, ink stains and local defects of a photosensitive layer after long-term storage can easily occur. Also, coarse aggregation substances of the Ti-B-based compounds and the Ti-C-based compounds can cause surface defects.
  • the contents of one or more types selected from B and C should be within 0.0001 to 0.0020%. The preferable range of the contents is 0.0003 to 0.0012%.
  • Mg is an element most of which is present as a solid solution in an aluminum alloy and which improves the strength of the support at normal temperature. Since it plays a role to improve the thermal softening resistance, in order to obtain the desired support strength and the thermal softening resistance, it may be contained in an amount exceeding 0% and not more than 0.5%. In this range, the characteristics of the aluminum alloy sheet for the lithographic printing plate are not damaged.
  • the pit uniformity after a roughening treatment is considered as the so-called electrolytic graining properties.
  • one or two or more types of 0.001 to 0.05% In, 0.001 to 0.05% Sn, 0.0001 to 0.01% Be, 0.001 to 0.05% Pb, and 0.001 to 0.05% Ni may be contained.
  • the characteristics of the aluminum alloy sheet for the lithographic printing plate are not damaged by an impurity amount corresponding to JIS1050, that is, at most 0.05% Mn, at most 0.05% Zn, at most 0.05% Zr, at most 0.05% Cr and approximately at most 0.05% in total of the other components.
  • the aluminum carbide is inevitably present in an aluminum metal. This is because, during electrolytic refining such as the three-layer electrolysis, a graphite used as an electrode is dissolved in an aluminum molten metal, and as the molten metal temperature is lowered during transfer or casting, an oversaturated carbon is separated as the aluminum carbide in the aluminum molten metal. Also, an amount of the aluminum carbide in the metal is largely fluctuated depending on metal manufacturers and metal manufacturing conditions. When an aluminum alloy containing a large amount of the aluminum carbide is used for a lithographic printing plate, an anodized film is not properly formed at a spot where the aluminum carbide is present.
  • the aluminum carbide is in contact with a fountain solution for a long time, the aluminum carbide is oxidized. And, it was found out that, since the hydrophilic nature is lowered in that portion, ink adheres thereto, and thus an ink stain occurs in a non-image area. Also, in the case of long-term storage in a state in which the aluminum carbide is present on the surface of the aluminum alloy sheet after a roughening treatment, the aluminum carbide is oxidized by the reaction with moisture in the atmosphere. As a result, an aluminum hydroxide and CH 4 gas generated by the reaction cause the lower adhesiveness with the photosensitive layer, and can easily cause a local defect in the photosensitive layer.
  • the aluminum carbide concentration should be at most 8 ppm. Also, it is preferable that an amount of aluminum carbide is low as little as possible, and the concentration of aluminum carbide is preferably at most 5 ppm or more preferably at most 3 ppm.
  • the aluminum carbide Since the aluminum carbide has the extremely low wettability with the aluminum, molten metal, it has the property that of easily existing on a solid-liquid interface between a solid such as a furnace wall, a hearth, a dross mainly composed of aluminum oxide and the like, and on the molten metal and a gas-liquid interface between a gas blown into the molten metal for hydrogen gas removal and the molten metal.
  • the aluminum carbide is present in the aluminum molten metal as a single body, the aluminum, carbide is discharged from the aluminum molten metal, and an amount of the aluminum carbide in the molten metal is decreased.
  • the aluminum carbide forms aggregation substances with these compounds.
  • These aggregation substances contain three types, the aggregation substance composed of the aluminum carbide and the Ti-B-based compound, the aggregation substance composed of the aluminum carbide and the Ti-C-based compound, and the aggregation substance composed of the aluminum carbide, the Ti-B-based compound, and the Ti-C-based compound.
  • These aggregation substances have the high wettability with the aluminum molten metal, and are hardly discharged from the molten metal.
  • an oversaturated carbon dissolved in the aluminum molten metal is separated as the aluminum carbide due to a lowered molten metal temperature.
  • the aluminum carbide is easily separated using these compounds as a starting point.
  • the above aggregation substance becomes a defect portion of the anodized film and causes an ink stain or a surface defect. Therefore, not only the control of the aluminum carbide concentration in the molten metal but also the control of the Ti content, the B content, and the C content are also required, and thus it is important to control the distribution state of the aggregation substances of the aluminum carbide and the above compounds on the surface of the aluminum alloy sheet.
  • the distribution of the aggregation substances composed of one or more types of compounds selected from the Ti-B-based compounds and the Ti-C-based compounds and the aluminum carbide is specified by (1) an area occupancy ratio of the aggregation substance on the surface of the aluminum alloy sheet to an area of an arbitrary circle having a radius of 5 ⁇ m; and by (2) the number of the aggregation substances present in an arbitrary area of 50 cm 2 on the surface of the aluminum alloy sheet.
  • the area occupancy ratio is less than 10%, there is no problem with occurrence of an ink stain or a defect of a photosensitive layer after long-term storage.
  • the distribution of the aggregation substances should be specified that the area occupancy ration is less than 10%, or that the number of the aggregation substances present in the area of 50 cm 2 is not more than 2, that is, 2 or 1, if the area occupancy ratio is not less than 10%.
  • a circle having a radius of 5 ⁇ m was provided around the aggregation substances as the center.
  • the area occupancy ratio was obtained by dividing a value of an area occupied by the aggregation substances by an area of the circle.
  • the area occupancy ratio of the aggregation substances and their number are measured by surface observation and qualitative analysis of the aluminum alloy sheet using an electronic probe microanalyzer (JXA-8200 by JEOL Ltd.).
  • the size of the aggregation substances to be a problem is a radius of not more than 5 ⁇ m in equivalent circle diameter. When the radius is larger than 5 ⁇ m, the area of the aggregation substances is too large and it is not a target of the present invention, and the ink stain and the photosensitive layer defect after long-term storage may occur substantially.
  • a method of manufacturing an aluminum alloy sheet for a lithographic printing plate according to the present invention is basically constituted by a melting step, a treatment step, a casting step, a homogenization step, a hot rolling step, an annealing step, a cold rolling step, and a surface treatment step. Since the amounts and the aggregation state of the aluminum carbide, the Ti-B-based compounds, and the Ti-C-based compounds are determined particularly by the melting step of the aluminum metal and the subsequent treatment step, the steps of melting and treatment are important in the present invention.
  • the aluminum molten metal temperature at the steps of melting an aluminum metal and treating the molten metal is less than 680 °C, aluminum metals and various master alloys for component adjustment are not fully melted. Also, since the molten metal temperature is further lowered in an in-line degassing treatment process and a filtration treatment process using an in-line filter, which will be described later which is included in the above treatment step, the aluminum alloy sheets cannot be stably produced. On the other hand, when the molten metal temperature exceeds 780 °C, the reaction between the aluminum molten metal and soot caused by imperfect combustion of fuel, carbon-containing compounds and the like in the treatment step is promoted, and the aluminum carbide is caused by the reaction.
  • the molten metal temperature exceeds 780 °C, an amount of carbon melted in the oversaturated state is increased, and the large amount of aluminum carbide is separated due to a lowered molten metal temperature in a stirring process, a retaining process, an in-line degassing process, and a filtration treatment process using an in-line filter, which are included in the treatment step. As a result, the aluminum carbide cannot be sufficiently removed.
  • the aluminum molten metal temperature at the stages of melting and treating should be 680 to 780 °C.
  • the preferable molten metal temperature is 680 to 750 °C.
  • the melted carbon and the separated aluminum, carbide are present as described above, and, in the aluminum metal prepared from this aluminum molten metal, a large amount of the separated aluminum carbide is contained.
  • the aluminum carbide is oxidized and this aluminum oxide is separated from the aluminum molten metal as dross so that the aluminum carbide can be reduced.
  • a stirring process, a retaining process, an in-line degassing treatment process, a filtration treatment process using an in-line filter, and a process of adding and stirring of a crystal grain refining agent are included in this order.
  • the molten metal subjected to the melting process is stirred by mechanical means or electromagnetic means over 5 to 60 minutes. Since a difference in the specific gravity between the aluminum carbide and the aluminum molten metal is small, a separation of the aluminum carbide from the aluminum molten metal takes a long time. Thus, by forcedly stirring the molten metal, the separation of the aluminum carbide from the aluminum molten metal is promoted.
  • the aluminum carbide separated from the aluminum molten metal is brought into contact with the atmosphere so as to be oxidized, resulting in generation of an aluminum oxide, and, by removing it from the aluminum molten metal, the aluminum carbide is removed, Also, since the aluminum carbide can easily exist in a solid-liquid interface, the aluminum carbide can be also removed from the aluminum molten metal by bringing the aluminum carbide into contact with the dross on the surface of the aluminum molten metal, a furnace wall and a furnace hearth.
  • the means for stirring the aluminum molten metal by operating a forklift, a crane and the like equipped with a stirring jig, or an electromagnetic stirring means using an electromagnetic stirring device and the like.
  • the stirring time is less than 5 minutes, the above-described stirring effect is not sufficient.
  • the stirring time exceeds 60 minutes, not only the stirring effect is saturated, inclusion such as oxides might be included easily, which can easily cause linear defects or ink stains derived from the inclusion.
  • the oxides reference may be made to an aluminum oxide generated by the reaction with oxygen in the atmosphere, an aluminum hydroxide generated by the reaction with moisture in the atmosphere, an aluminum oxide containing water and the like.
  • the stirring time should be 5 to 60 minutes.
  • the preferable stirring time is 10 to 50 minutes.
  • a hydrogen gas removing process may be carried out by blowing an argon gas, a chlorine gas or a mixed gas of them into the aluminum molten metal in the furnace.
  • the stirring effect can be also obtained from this treatment. That is because inclusions such as the aluminum carbide is adsorbed by gas bubbles, and the gas bubbles float in that state so that the inclusions are separated from the aluminum molten metal as the dross.
  • the aluminum molten metal is subjected to the holding process. Since the aluminum carbide is poor in the wettability with the aluminum molten metal, the aluminum carbide settles down, or floats by fluidization of the molten metal by the holding process. By this settling or floating, the aluminum carbide can be separated. The separation using a difference in the specific gravity between the inclusion such as the aluminum oxide and the aluminum molten metal is also possible.
  • the holding time is less than 10 minutes, the above-described separation effect is not sufficient. On the other hand, when the holding time exceeds 60 minutes, the effect is saturated, which is not preferable economically. Thus, the holding time should be 10 to 60 minutes. The preferable holding time is 20 to 60 minutes.
  • the molten metal is subjected to the in-line degassing treatment process.
  • an in-line degassing treating device those sold in the market with the trademarks such as SNIF or ALPUR can be used.
  • an argon gas or a mixed gas of argon and chlorine is blown into the molten metal
  • a rotary body with a blade is rotated at a high speed so as to supply the gas in fine bubbles into the molten metal. Removal of hydrogen gas and inclusions can be performed in-line in a short time.
  • the above stirring effect can be obtained, and the aluminum carbide in the molten metal can be further decreased.
  • the aluminum molten metal is filtered by an in-line filter.
  • an in-line filter a ceramic tube filter, a ceramic foam filter, an alumina ball filter or the like may be used so as to remove inclusions by a cake filtration mechanism or a filter element filtration mechanism.
  • a filter By filtering the aluminum molten metal by the filtration mechanism using a filter, not only the aluminum carbide but also inclusions such oxides including the aluminum oxide can be removed.
  • Ti-B-based aluminum alloys In order to refine crystal grains of an ingot structure, as a crystal grain refining agent, massive or linear Ti-based aluminum alloys, Ti-B-based aluminum alloys, Ti-C-based aluminum alloys and the like are added. As described above, an added amount as content of one or more types selected from B and C is within a range of 0.0001 to 0.0020%.
  • the Ti-B-based aluminum alloys and the Ti-C-based aluminum alloys have the greater crystal grain refining effect than the Ti-based aluminum alloys, but they also have a defect that surface defects caused by the aggregation substances of the Ti-B-based compounds or the Ti-C-based compounds contained in these aluminum alloys can easily occur.
  • the aggregation of the Ti-B-based compounds or the Ti-C-based compounds is prevented by controlling the added amount of the crystal grain refining agent or the B amount and the C amount, and by performing a molten metal treatment in which the aggregation is not caused. Specifically, by setting the time during which the crystal grain refining agent is added to the molten metal, and is stirred within 10 minutes, the aggregation by stirring is prevented.
  • the stirring there are the above mechanical or electromagnetic stirring process, a bubbling for hydrogen gas removal, and an in-line degassing treatment process.
  • the aluminum molten metal to which the crystal grain refining agent is added is stirred over more than 10 minutes, the aggregation of the Ti-B-based compound and the Ti-C-based compound occurs, and linear defects can easily occur. Also, since the Ti-B-based compound and the Ti-C-based compound are present as solid in the aluminum molten metal, the aluminum carbide is adsorbed by this solid-liquid interface, which makes the separation from the aluminum molten metal difficult.
  • the aggregation substances of the aluminum carbide and the Ti-B-based compound and the aggregation substances of the aluminum carbide and the Ti-C-based compound can cause ink stains and a photosensitive layer defect after long-term storage easily.
  • the preferable stirring time is within 5 minutes.
  • the molten metal having subjected to the melting and treatment steps as above is cast to an ingot in accordance with a common procedure by a DC casting method and the like. Instead, it may be cast by a continuous casting method using a driving casting mold.
  • An ingot obtained as above is subjected to the homogenization treatment step, the hot rolling step, the annealing step, the cold rolling step and the like in accordance with a usual procedure as described below, and is finally molded into a rolled sheet having the desired sheet thickness.
  • the ingot is usually subjected to the homogenization treatment step at 450 to 620 °C.
  • impurity elements are diffused, and thus the pit generation in an electrolytic graining is further uniform.
  • crystal grains in an intermediate annealing can be refined more easily.
  • the holding time of the homogenization treatment step can be suitably determined depending on a size of the ingot or the like, but it is usually 0.5 to 20 hours. If the time is less than 0.5 hours, the sufficient homogenization effect cannot be obtained in some cases. On the other hand, when the time exceeds 20 hours, each of the above effects is saturated, which is not preferable economically.
  • the ingot may be subjected to a heating treatment process for the hot rolling step after the ingot is once cooled to a room temperature, or the hot rolling step may be performed after the ingot is cooled to 350 to 500 °C after the homogenization treatment step.
  • the hot rolling is preferably started at the temperature of 350 to 500 °C. If the hot rolling start temperature is less than 350 °C, re-crystallization is not realized during the hot rolling step, and crystal grains of the ingot still remain in the hot rolled plate. Thus, when the final hot rolled plate is subjected to an electrolytic graining treatment process, a band-like or stripe-like appearance unevenness (streaks) may occur, which makes the surface appearance of the printing plate non-uniform. On the other hand, if the hot rolling start temperature exceeds 500 °C, re-crystallized grains are made coarse during the hot rolling step, the streaks occur in the surface of the sheet after the electrolytic roughening treatment process, which may make the surface appearance non-uniform,
  • the hot rolling end temperature is set at 300 to 350 °C
  • the self-re-crystallization can be realized by utilizing heat derived from the hot rolling step.
  • the entire plate after the hot rolling step can be made a refined re-crystallization structure. Due to the self-re-crystallization, the annealing step after the hot rolling step is no longer needed, and a reduction of a manufacturing cost can be expected.
  • the end temperature is less than 300 °C, the surface of the hot rolled plate is partially re-crystallized, and the appearance after the roughening treatment process may become non-uniform.
  • crystal grains may be further refined as compared with the above-described self-crystallization process material so as to increase uniformity of the appearance after the roughening treatment process.
  • the hot rolling end temperature is less than 200 °C
  • rolling oil is not fully evaporated, but remains on the surface of the final hot rolled plate and might cause surface stains or corrosion.
  • the end temperature exceeds 300 °C, since the accumulated dislocation is not sufficient, the crystal grains are not refined by the annealing step, and the appearance after the roughening treatment process may become non-uniform.
  • the above annealing step by treating the rolled plate at 400 to 550 °C in a continuous annealing furnace for 0 to 60 seconds or at 300 to 500 °C in a batch furnace for 1 to 20 hours after the end of the hot rolling step and before the end of the cold rolling step, crystal grains are refined, and the appearance after the roughening treatment process becomes uniform.
  • the annealing step in the continuous annealing furnace when the temperature is less than 400 °C, the effect may not be sufficient.
  • the annealing step at more than 550 °C or over more than 60 seconds the effect is saturated, which is not preferable economically.
  • the annealing step in the batch furnace when the temperature is less than 300 °C, the single Si can be easily separated, and the effect of crystal grain refining may not be sufficient. Also, when the annealing time is less than 1 hour, the effect of crystal grain refining may not be sufficient. In the case of the annealing step at more than 500 °C or over more than 20 hours, the crystal grains become coarse and the appearance after the roughening treatment process may become non-uniform.
  • Conditions for the cold rolling step are not particularly limited, and it is only necessary to follow a normal procedure.
  • the final cold rolling ratio may be determined in accordance with the required strength or the thickness of the product sheet, and it is only necessary that the cold rolling step is carried out with rolling reduction of 60 to 98%. Straightening with a leveler may be performed after the final cold rolling step.
  • a surface treatment step for roughening, anodization and the like is carried out.
  • This surface treatment method is not particularly limited, and utilizes any one of or two or more in combination of a mechanical method, a chemical method, and an electrochemical method which are performed according to a normal procedure.
  • An etching amount by the surface treatment is preferably 1 to 10 ⁇ m from the surface of the aluminum alloy sheet. With the etching amount less than 1 ⁇ m, the roughening may be insufficient, and the plate wear resistance may be poor. On the other hand, if the etching amount exceeds 10 ⁇ m, the etching amount is too large, which is not preferable economically.
  • a photosensitive layer is applied to the aluminum alloy sheet for a lithographic printing plate obtained by the above steps, and the resulting plate is dried so that the lithographic printing plate support is obtained.
  • the aluminum metal was melted at 745 °C. Then, the molten metal was mechanically stirred at 745 °C over 30 minutes, using a stirring machine provided with three blades. Moreover, the molten metal was held at 735 °C over 40 minutes. Then, the in-line degassing treatment process was carried out by blowing argon gas into the molten metal, using the in-line degassing treatment device (SNIF), Moreover, the aluminum carbide and oxides were removed by filtering the molten metal by using a ceramic tube filter as an in-line filter.
  • SNIF in-line degassing treatment device
  • a crystal grain refining agent was added so as to have a concentration as described in each of compositions A to Z and a to g.
  • the stirring time from the addition of the crystal grain refining agent was 0 minutes.
  • the temperature of the molten metal from the in-line degassing treatment process to the addition of the crystal grain refining agent was 700 °C.
  • the molten metal having been subjected to the melting and treatment steps as above was cast in accordance with the normal procedure of the DC casting method so as to fabricate an ingot of the aluminum alloy.
  • This ingot was subjected to the homogenization treatment step under the condition of 560 °C and 6 hours. After that, the ingot was cooled to a room temperature once, and was then heated to 430 °C for the hot rolling step. Subsequently, the hot rolling step with the start temperature of 425°C and the end temperature of 320 °C was carried out. Moreover, the cold rolling step with the rolling reduction of 85% was carried out so as to obtain the aluminum alloy sheet for a lithographic printing plate with the thickness of 0.30 mm.
  • the aluminum carbide concentration was measured in compliance with an alkali hydroxide Cracked gas chromatography method described in LIS A09-1-1971 (LIS: Light Metal Industrial Standard) as follows: An amount of 0.2 g of the aluminum alloy sheet fabricated as above was put into a reaction tank, and air in the inside of the tank is fully replaced with He. After the replacement of air with, a NaOH aqueous solution (20 volumetric %, approximately 20 ml) was dripped using a dripping funnel. Immediately after the dripping, the stirring step was performed by rotating a stirrer, while the reaction tank was heated, so that the aluminum alloy sample containing the aluminum carbide and the NaOH aqueous solution were fully reacted with each other.
  • LIS A09-1-1971 LIS: Light Metal Industrial Standard
  • CH 4 generated by the reaction between the aluminum carbide and moisture is trapped by an active coal column immersed in liquid N 2 .
  • the trapped CH 4 was evaporated by immersing the active coal column in water bath.
  • the quantity of the evaporated CH 4 was determined by a gas chromatography (HP6890 by Hewlett Packard).
  • a CH 4 amount was determined using a calibration curve using a standard gas obtained by diluting CH 4 with N 2 and preparing in advance. Subsequently, this CH 4 amount was converted to the aluminum carbide concentration.
  • Al4C 3 , Al 2 C 6 , Al 4 O 4 C and the like can be cited, but as the aluminum carbide converted as the aluminum carbide concentration was represented by Al 4 C 3 .
  • the aluminum carbide concentration acquired as above was evaluated, and the concentration not more than 8 ppm is acceptable, while the concentration exceeding 8 ppm is rejected. The results are shown in Table 2.
  • the aluminum carbide concentration in the used aluminum metal was measured in advance, and it was 18 ppm.
  • the obtained aluminum alloy sheet was immersed in a 10 mass% aqueous sodium hydroxide solution at 70 °C for 30 seconds and etched, and was washed with flowing water. Then, the washed sheet was neutralized with a 20 mass% nitric acid aqueous solution, and was further washed with water.
  • this aluminum alloy sheet was immersed in a 30 mass% sulfuric acid aqueous solution at 55 °C, and is subjected to a desmutting process for 2 minutes. Thereafter, in a 20 mass% sulfuric acid aqueous solution at 33 °C, a cathode was arranged on the grained surface, and the aluminum alloy sheet was anodized at a current density of 5A/dm2 for 50 seconds. The anodized film amount was 2.6 g/m2.
  • the aluminum alloy sheet subjected to the above surface treatment step was made to be a support 1.
  • the area occupancy ratio of the aggregation substances of the Ti-B-based compound and the aluminum carbide, the Ti-C-based compound and the aluminum carbide, and the Ti-B-based compound, the Ti-C-based compound and the aluminum carbide distributed within 50 cm 2 on the surface of the aluminum alloy sheet subjected to the above surface treatment step were measured using an electronic probe microanalyzer. Measurement spots were determined by arbitrarily selecting 20 pieces of the aggregation substances. A circle having a radius of 5 ⁇ m was provided around the selected the aggregation substances as the center, and the area occupancy ratio of the aggregation substances with respect to the circle was measured. The area occupancy ration was obtained by dividing a value of an area occupied by the each aggregation substances by an area of the circle. The each area occupancy ration less than 10% was rated as acceptable. The result is shown in Table 2.
  • the measurement when there are the aggregation substances with the area occupancy ratio of not less than 10%, the number thereof was counted.
  • the number of the aggregation substances present within a range of 50 cm 2 being 1 or 2 was rated as acceptable, while the number exceeding 2 was rated as rejected.
  • the result was shown in Table 2.
  • the measurements of the area occupancy ratio and the number of the aggregation substances on the surface of the aluminum alloy sheet are preferably made on the support 1 which is subjected to the above surface treatment step, but since fine scars or projections and recesses caused by the roughening treatment are present, the discrimination may be difficult. In that case, the measurement may be made on the surface which is subjected to a smoothing treatment.
  • the smoothing treatment method includes mechanical polishing, electrolytic polishing and the like. Also, the polishing depth should be 1 to 10 ⁇ m, and it is important that it should be equal to the depth to be etched by the above surface treatment step. Also, since the aluminum carbide is oxidized by the reaction with moisture and oxygen in the atmosphere, the measurement needs to be made quickly after the surface treatment step.
  • This support 1 was coated with a base coating liquid having the following composition so that a dried application amount becomes 2 mg/m 2 using a bar coater and was dried at 80 °C for 20 seconds, to thereby obtain a support 2.
  • This support 2 was coated with a photosensitive substance having the following composition using a bar coater, and then it was dried at 90 °C for 1 minute, to thereby form a photosensitive layer.
  • the mass of the dried photosensitive layer was 1.35 g/m 2 .
  • This photosensitive layer was coated with a protective layer application aqueous solution having the following composition using a bar coater so that a dried application mass becomes 2.5 g/m 2 , and was dried at 120 °C for 1 minute, to thereby obtain a photosensitive lithographic printing plate original plate.
  • the obtained photosensitive printing plate was adjusted with Vx9600CTP by Fuji Film Corporation (light-source wavelength: 405 nm) so that an exposure amount on a sensitizing material is 0.05 mJ/cm 2 and drawing was made in an image state. Thereafter, a preheating was performed within 30 seconds, and a development was made by the developing solution at 25 °C using PS processor Inter Plater 850HD by G&J in which an alkali developing solution having the following composition was incorporated.
  • the developed lithographic printing plate was washed with water and dried, and a printing test using 100 thousand copies was carried out using an offset rotary press. Thereafter, a degree of dot-like stains in a non-image area was visually evaluated. Evaluation was made such that a favorable copy without dot-like stains over the entire non-image area was rated as very good ( ⁇ ), a copy with some dot-like stains but without a practical problem was rated as good ( ⁇ ), and a copy with dot-like stains causing a practical problem was rated as poor ( ⁇ ). The ⁇ and ⁇ marks were rated as acceptable, while the ⁇ mark was rated as rejected. The result is shown in Table 2.
  • the lithographic printing plate on which the photosensitive layer was formed as above was stored for three months under the atmosphere at a room temperature and the humidity within a range of 20 to 90%, and occurrence of a defect in the photosensitive layer was evaluated. Evaluation was made such that a plate without defects in the photosensitive layer was rated as very good ( ⁇ ), a plate with some defects but without a practical problem was rated as good ( ⁇ ), and a plate with defects causing a practical problem was rated as poor ( ⁇ ). The ⁇ and ⁇ marks were rated as acceptable, while the ⁇ mark was rated as rejected. The result is shown in Table 2.
  • the aluminum carbide concentration was not more than 8 ppm
  • the area occupancy ratio of the aggregation substances was less than 10%.
  • the area occupancy ratio is not less than 10%
  • the density of the aggregation substances was not more than 2 per 50 cm 2 . Both the cases were acceptable.
  • the pit uniformity after the roughening, the ink stain resistance, and the fault tolerance of the photosensitive layer after long-term storage were all acceptable.
  • Comparative Example 23 since the Fe content of the aluminum alloy W was too small, the pits generated by the roughening treatment were non-uniform. In Comparative Example 24, since the Fe content of the aluminum alloy X was too large, the pits generated by the roughening treatment were non-uniform. In Comparative Example 25, since the Si content of the aluminum alloy Y was too small, the pits generated by the roughening treatment were non-uniform. In Comparative Example 26, since the Si content of the aluminum alloy Y was too large, the pits generated by the roughening treatment were non-uniform, and also the single Si was separated, to thereby causing ink stains.
  • Comparative Example 27 since the Cu content of the aluminum alloy a was too small, the pits generated by the roughening treatment were non-uniform. In Comparative Example 28, since the Cu content of the aluminum alloy b was too large, the pits generated by the roughening treatment were non-uniform. In Comparative Example 29, since the Ti content of the aluminum alloy c was too small, the pits generated by the roughening treatment were non-uniform. In Comparative Example 30, since the Ti content of the aluminum alloy d was too large, the coarse Al-Ti-based compound was formed, and ink stains occurred. In Comparative Example 31, since the total contents of B and C of the aluminum alloy e was too small, the pits generated by the roughening treatment were non-uniform.
  • Comparative Example 32 since the content of B of the aluminum alloy f was too large, the total contents of B and C were too large, too. As a result, the aluminum carbide concentration was too high, the aggregation density of the Ti-B-based compound was also too large, and ink stains and a local defect in the photosensitive layer after long-term storage occurred. Moreover, a defect occurred on the surface by an aggregation of the Ti-B-based compound. In Comparative Example 33, since the content of C of the aluminum alloy g was too large, the total contents of B and C were too large, too.
  • the aluminum carbide concentration was too high, the aggregation density of the Ti-C compound was also too large, and ink stains and a local defect in the photosensitive layer after long-term storage occurred. Moreover, a defect occurred on the surface by an aggregation of the Ti-C-based compound.
  • the aluminum metal was subjected to the melting step and the treatment step described in Table 3.
  • the molten metal temperature in the stirring process after the melting process was the same as the temperature in the melting process.
  • the molten metal temperature in the stirring process was the same as the molten metal temperature in the filtration treatment process using the in-line filter.
  • the molten metal subjected to the melting process and the treatment processes as above was cast in compliance with the normal procedure of the DC casting method, to thereby fabricate an ingot of the aluminum alloy.
  • the obtained ingot was subjected to the homogenization treatment step under the condition of 540 °C and 3 hours. Thereafter, the ingot was cooled to a room temperature once, and was then heated to 420 °C for the hot rolling step. Subsequently, the ingot was subjected to the hot rolling step with the start temperature of 415 °C and the end temperature of 330 °C. Moreover, the hot rolled aluminum alloy plate was subjected to the cold rolling step with rolling reduction of 80% to thereby obtain an aluminum alloy sheet for a lithographic printing plate with the thickness of 0.3 mm.
  • the obtained aluminum alloy sheet for a lithographic printing plate was subjected to the same surface treatment step as in the above-described Invention Example 1, and was made to be the aluminum alloy sheet support 1.
  • the area occupancy ratio of aggregation substances of the Ti-B-based compound and the aluminum carbide, the Ti-C-based compound and the aluminum carbide, and the Ti-B-based compound, the Ti-C-based compound and the aluminum carbide on the surface of the support 1 were measured and evaluated similarly to the example 1.
  • the area occupancy of the aggregation substances is not less than 10%
  • the number of the aggregation substances was measured and evaluated similarly to the example 1.
  • the pit uniformity after the roughening was also evaluated similarly to the example 1. The results are shown in Table 4.
  • the support 1 was coated with the base coating liquid, and was dried to thereby obtain the support 2.
  • the support 2 was coated with the photosensitive composition, and was dried to thereby form the photosensitive layer.
  • the formed photosensitive layer was coated with the protective layer application aqueous solution, and was dried to thereby obtain the photosensitive lithographic printing plate original plate.
  • the aluminum carbide concentration was not more than 8 ppm
  • the area occupancy ratio of the aggregation substances was less than 10%.
  • the area occupancy ratio is not less than 10%
  • the density of the aggregation substances was not more than 2 per 50 cm 2 . Both the cases were acceptable.
  • the pit uniformity after the roughening, the ink stain resistance, and the fault tolerance of the photosensitive layer after long-term storage were all acceptable.
  • Comparative Example 50 due to the fact that the molten metal temperature during the melting stage was too high, soot caused by imperfect combustion of fuel, carbon-containing compounds and the like were reacted with the molten metal, and the aluminum carbide was generated, resulting in increase in its concentration. Further, the aggregation substance density with the Ti-B-based compound was too high. As a result, ink stains at printing and defects in the photosensitive layer after long-term storage occurred. In Comparative Example 51, since the molten metal temperature during the melting stage was too low, an aluminum metal and a mother alloy were not fully melted, and the aluminum alloy sheet could not be produced stably.
  • Comparative Example 52 since the stirring time after the melting stage was too short, the effect of the aluminum carbide removal by stirring was not sufficient, the concentration became high, and the aggregation substance density with the Ti-B-based compound was too high. As a result, ink stains at printing and defects in the photosensitive layer after long-term storage occurred. In Comparative Example 53, since the stirring time after the melting stage was too long, inclusions was included. As a result, ink stains occurred. Moreover, defects were caused on the surface.
  • Comparative Example 54 due to the fact that the molten metal temperature in the retaining process was too high, soot caused by imperfect combustion of fuel, carbon-containing compounds and the like were reacted with the molten metal, the aluminum carbide was generated, resulting in increase in its concentration. Further, the aggregation substance density with the Ti-B-based compound was too high. As a result, ink stains at printing and defects in the photosensitive layer after long-term storage occurred. In Comparative Example 55, since the retaining time was too short, a separation of the aluminum carbide was insufficient, the concentration became high. Further, the aggregation substance density with the Ti-B-based compound was too high.
  • the aggregation substance density with the Ti-B-based compound was too high. As a result, ink stains caused by the aluminum carbide and defects in the photosensitive layer after long-term storage occurred. Also, inclusions caused surface defects and ink stains.
  • Comparative Example 60 due to the fact that the stirring time of the aluminum molten metal after the addition of the crystal grain refining agent was too long, the concentration of the aluminum carbide became high. Further, the aggregation substance density with the Ti-B-based compound was too high. As a result, ink stains and defects in the photosensitive layer after long-term storage occurred. Also, an aggregation of the Ti-B compound occurred, which caused a surface defect.
  • an aluminum alloy sheet for a lithographic printing plate which is excellent in the pit uniformity after roughening, the ink stain resistance in a non-image area during printing, and the fault tolerance of a photosensitive layer in storage under the atmosphere can be obtained. Also, according to the manufacturing method of an aluminum alloy sheet for a lithographic printing plate according to the present invention, the aluminum alloy sheet for the lithographic printing plate can be obtained reliably and stably.

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CN111471878A (zh) * 2020-04-16 2020-07-31 西南铝业(集团)有限责任公司 一种4004铝合金铸锭的熔铸工艺
CN111719059A (zh) * 2020-06-11 2020-09-29 新疆众和股份有限公司 一种溅射用细晶高纯铝硅铜合金靶材坯料的制备方法
CN113322400A (zh) * 2020-02-28 2021-08-31 株式会社神户制钢所 铝合金锻造材及其制造方法

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JP6087413B1 (ja) * 2015-11-05 2017-03-01 株式会社神戸製鋼所 レーザー溶接性に優れた自動車バスバー用アルミニウム合金板
BR112019002424A2 (pt) * 2016-09-01 2019-06-04 Novelis Inc liga de alumínio, e, placa litográfica de liga de alumínio
JP6506897B1 (ja) 2018-10-15 2019-04-24 株式会社Uacj 磁気ディスク用アルミニウム合金板及びその製造方法、ならびに、当該磁気ディスク用アルミニウム合金板を用いた磁気ディスク
CN111254293B (zh) * 2020-01-19 2022-04-12 闽南理工学院 一种铝箔坯料的制备净化处理方法

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CN111471878A (zh) * 2020-04-16 2020-07-31 西南铝业(集团)有限责任公司 一种4004铝合金铸锭的熔铸工艺
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