CN1311940C - Method for founding aluminium alloy slab ingot - Google Patents
Method for founding aluminium alloy slab ingot Download PDFInfo
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- CN1311940C CN1311940C CNB2005100099997A CN200510009999A CN1311940C CN 1311940 C CN1311940 C CN 1311940C CN B2005100099997 A CNB2005100099997 A CN B2005100099997A CN 200510009999 A CN200510009999 A CN 200510009999A CN 1311940 C CN1311940 C CN 1311940C
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Abstract
The present invention discloses a fusion casting method for aluminium-Si-Mg alloy casting ingot. The aluminium alloy flat ingot casting technology method has the following steps: alloy raw materials are heated to 740 DEG C to 760 DEG C, are simultaneously stirred and remove slag; elements has the proportioning that 0.6% to 0.8 of SiO, 0.4% to 0.7 of Fe, 0.15 to 0.4 of Cu, 0 to 0.5 of Mn, 0.8 to 1.2 of Mg, 0.04 to 0.35 of Cr, 0 to 0.25 Zn, 0 to 0.15 Ti, other single impurity is equal to or less than 0.05%, other impurity total is equal to or less than 0.10%, and the rest is Al; chlorine gas is introduced to the bottom of alloy fusing liquid for smelting; the alloy fusing liquid is poured in an ingot mould 1 which is placed on a sliding platform 2 driven by a hydraulic system 3; the sliding platform 2 moves on a guide track 4, and the ingot mould 1 moves along with the sliding platform 2; the alloy fusing liquid is poured from one end of a mould cavity to the other end of the mould cavity; the sliding platform 2 moves, and simultaneously, Al-Ti-B wires are fast inserted in the alloy fusing liquid. The present invention has the advantages of high productive efficiency and good product quality.
Description
Technical field:
The present invention relates to the casting method that a kind of aluminium-silicon-magnesium is alloy cast ingot.
Background technology:
At present in order to enhance productivity, the Production Line ability often will improve in the manufacturer of each aluminium alloy cast ingot, inefficient production line and production technology are eliminated, the substitute is new production line and production technology, wherein using 25 tons of oil ovens to come the cast production line of 6061 alloy flat ingot castings of molten alloy is exactly a kind of production line newly developed.The advantage of this production line is the production efficiency height, and the aluminium ingot of production is that length is that 1320 millimeters, width are that 300 millimeters, thickness are the slab ingot of 150 millimeter.The aluminium ingot of this shape advantage easily that has processing, transports and store in a warehouse, therefore be subjected to very much user's welcome, but the shortcoming that exists is: the aluminium ingot workmanship of this shape is not easy to be guaranteed, and has crackle in the aluminium ingot easily.
Summary of the invention:
In order to overcome the defective that occurs crackle with 25 tons of oil ovens come molten alloy to cast aluminium ingot that the production line of 6061 alloy flat ingot castings produces easily, provide a kind of finished product ingot casting the method for founding aluminium alloy slab ingot of crackle can not occur.Technical scheme of the present invention realizes by following step: one, alloy raw material is heated to 740~760 ℃, heating the time is stirred and is skimmed, the mass percent of each element is controlled to be Si:0.60~0.8%, Fe:0.4~0.7%, Cu:0.15~0.40%, Mn:0~0.15%, Mg:0.8~1.2%, Cr:0.04~0.35%, Zn:0~0.25%, Ti:0~0.15%, other single impurity≤0.05% in the alloy, other impurity add up to≤0.10%, and all the other are Al; Two, feed chlorine to the bottom of alloy liquation, the temperature that keeps the alloy liquation simultaneously melting 25~35 minutes between 700~740 ℃ was left standstill 15~25 minutes then; Three, the alloy liquation is poured into a mould in the end of the die cavity 1-1 of ingot mould 1 strip, ingot mould 1 is placed on the sliding platform 2 that is driven by hydraulic system 3, sliding platform 2 moves on guide rail 4, ingot mould 1 is with sliding platform 2 motions, the alloy liquation is poured into the other end of die cavity 1-1 from the end of die cavity 1-1, in sliding platform 2 motion, in the alloy liquation, at the uniform velocity insert the Al-Ti-B silk, each element in the Al-Ti-B silk is evenly fused in the alloy liquation along the length direction of die cavity 1-1.Because the content basic controlling of Fe is more than 0.4% in the alloying element of this ingot casting, the content basic controlling of Si makes the microscopic structure of alloy crystal fine and close more than 0.6%, has reduced the possibility that crackle takes place; The bottom of alloy liquation feeds chlorine the hydrogen in the liquation or other gas displacement is come out, and effectively improves the quality of ingot casting.Hydraulic system has stable drive, accurate, the safe and reliable advantage of speed control, make ingot mould 1 move not only exactly but also adjustable-speed, so casting process is very steady, has reduced the possibility of ingot casting bending, avoid ingot casting inside stress to occur, reduced the possibility that crackle occurs.Method of the present invention has the advantage of production efficiency height, good product quality, has higher promotional value.
Description of drawings:
Fig. 1 is the structural representation of the inventive method institute operative installations.
The specific embodiment:
The specific embodiment one: specify present embodiment below in conjunction with Fig. 1.Present embodiment is realized by following step: one, alloy raw material is heated to 740~760 ℃, heating the time is stirred and is skimmed, the mass percent of each element is controlled to be Si:0.60~0.8%, Fe:0.4~0.7%, Cu:0.15~0.40%, Mn:0~0.15%, Mg:0.8~1.2%, Cr:0.04~0.35%, Zn:0~0.25%, Ti:0~0.15%, other single impurity≤0.05% in the alloy, other impurity add up to≤0.10% all the other be Al; Two, feed chlorine to the bottom of alloy liquation, the temperature that keeps the alloy liquation simultaneously melting 25~35 minutes between 700~740 ℃ was left standstill 15~25 minutes then; Three, the alloy liquation is poured into a mould in the end of the die cavity 1-1 of ingot mould 1 strip, ingot mould 1 is placed on the sliding platform 2 that is driven by hydraulic system 3, sliding platform 2 moves on guide rail 4, ingot mould 1 is with sliding platform 2 motions, the alloy liquation is poured into the other end of die cavity 1-1 from the end of die cavity 1-1, in sliding platform 2 motion, in the alloy liquation, at the uniform velocity insert the Al-Ti-B silk, each element in the Al-Ti-B silk is evenly fused in the alloy liquation along the length direction of die cavity 1-1.It is Ti:5% that the Al-Ti-B silk is selected the component of selling on the market for use, B:1%, Al: the Al-Ti-B silk of surplus.The addition of Al-Ti-B silk is to add 0.9~1.1 kilogram of Al-Ti-B silk in the alloy liquation per ton.Casting process mid point Al-Ti-B silk is to realize that alloy melt is carried out refinement.
The specific embodiment two: the difference of present embodiment and embodiment one is: in step 3, during from 0 to 90 millimeter of sliding platform 2 displacement, the translational speed of sliding platform 2 is 50 mm/min, and the displacement of sliding platform becomes 55 mm/min greater than translational speed after 90 millimeters.It is slower that setting like this begins with ingot mould 1 contact velocity the alloy liquation, and the too fast stress that produces inhomogeneous contraction in ingot casting of cooling velocity reduces the generation of crackle when avoiding beginning.
The specific embodiment three: the difference of present embodiment and embodiment one is: in step 1, alloy raw material is heated to 740 ℃, heating the time is stirred and is skimmed, and the mass percent of each element is controlled to be Si:0.60%, Fe:0.4%, Cu:0.15%, Mg:0.8%, Cr:0.04% in the alloy, all the other are Al; Feed chlorine to the bottom of alloy liquation in step 2, the temperature that keeps the alloy liquation simultaneously melting 25 minutes between 700 ℃ was left standstill 15 minutes then; Other step is identical with embodiment one.
The specific embodiment four: the difference of present embodiment and embodiment one is: in step 1, alloy raw material is heated to 760 ℃, heating the time is stirred and is skimmed, the mass percent of each element is controlled to be Si:0.8%, Fe:0.7%, Cu:0.40%, Mn:0.15%, Mg:1.2%, Cr:0.35%, Zn:0.25%, Ti:0.15%, other single impurity≤0.05% in the alloy, other impurity add up to≤0.10%, and all the other are Al; Feed chlorine to the bottom of alloy liquation in step 2, the temperature that keeps the alloy liquation simultaneously melting 35 minutes between 740 ℃ was left standstill 25 minutes then; Other step is identical with embodiment one.
The specific embodiment five: the difference of present embodiment and embodiment one is: in step 1, alloy raw material is heated to 750 ℃, heating the time is stirred and is skimmed, the mass percent of each element is controlled to be Si:0.7%, Fe:0.55%, Cu:0.27%, Mn:0.075%, Mg:1.0%, Cr:0.20%, Zn:0.12%, Pi:0.075%, other single impurity≤0.05% in the alloy, other impurity add up to≤0.10%, and all the other are Al; Feed chlorine to the bottom of alloy liquation in step 2, the temperature that keeps the alloy liquation simultaneously melting 30 minutes between 740 ℃ was left standstill 20 minutes then; Other step is identical with embodiment one.In ingot casting, get some samples through the mirco structure inspection, do not find that microscopic structure is loose, measure dendrite interval with the quantitative metallography microscope, second phase volume fraction (homogenising state sample can not the equal crystallite dimension of lining), it the results are shown in Table 1.As can be seen from Table 1, each sample mean dendrite interval is 65.46 μ m, and second size mean value is 3.81 μ m, illustrates that the dendrite net is less.Mg, the segregation of Si elemental composition the results are shown in Table 2, and the chemical composition on the ingot casting section is even substantially as can be seen.The mechanical property check result sees Table 3, and as can be seen from the table, yield strength mean value is 114N/mm
2, tensile strength mean value is 188N/mm
2, and absolute percentage elongation mean value is 18.0%, its casting and processing technology plasticity are all very good.
Table 1
|
|
|
On average | |
Second size (μ m) | 4.01 | 3.75 | 3.68 | 3.81 |
Dendrite interval (μ m) | 68.10 | 66.43 | 61.86 | 65.46 |
Second phase volume fraction (%) | 5.54 | 5.26 | 5.55 | 5.45 |
Table 2
Composition % | Segregation % | |||
|
|
|
||
Si | 0.62 | 0.63 | 0.61 | 0.02 |
Mg | 0.96 | 0.97 | 0.97 | 0.01 |
Table 3
Wipe away sample number | Yield strength | Tensile strength | The absolute elongation amount | |
1 | 106 | 173 | 8.0 | 17.8 |
2 | 117 | 177 | 7.4 | 16.4 |
3 | 117 | 185 | 6.8 | 15.1 |
4 | 116 | 199 | 7.9 | 17.5 |
5 | 116 | 198 | 8.0 | 17.8 |
6 | 115 | 185 | 9.0 | 16.4 |
7 | 107 | 197 | 10.5 | 15.1 |
8 | 115 | 191 | 7.2 | 17.5 |
Mean value | 114 | 188 | 8.1 | 18.0 |
Claims (6)
1, method for founding aluminium alloy slab ingot, it is characterized in that it realizes by following step: one, alloy raw material is heated to 740~760 ℃, heating the time is stirred and is skimmed, the mass percent of each element is controlled to be Si0.60~0.8%, Fe0.4~0.7%, Cu0.15~0.40%, Mn0~0.15%, Mg0.8~1.2%, Cr0.04~0.35%, Zn0~0.25%, Ti0~0.15%, other single impurity≤0.05% in the alloy, other impurity add up to≤0.10%, and all the other are Al; Two, feed chlorine to the bottom of alloy liquation, the temperature that keeps the alloy liquation simultaneously melting 25~35 minutes between 700~740 ℃ was left standstill 15~25 minutes then; Three, the alloy liquation is poured into a mould in an end of the die cavity (1-1) of ingot mould (1) strip, ingot mould (1) is placed on the sliding platform (2) that is driven by hydraulic system (3), sliding platform (2) is gone up motion at guide rail (4), ingot mould (1) moves with sliding platform (2), the alloy liquation is poured into the other end of die cavity (1-1) from an end of die cavity (1-1), in sliding platform (2) motion, in the alloy liquation, at the uniform velocity insert the Al-Ti-B silk, each element in the Al-Ti-B silk is evenly fused in the alloy liquation along the length direction of die cavity (1-1).
2, method for founding aluminium alloy slab ingot according to claim 1, the addition that it is characterized in that the Al-Ti-B silk are to add 0.9~1.1 kilogram of Al-Ti-B silk in the alloy liquation per ton.
3, method for founding aluminium alloy slab ingot according to claim 1, it is characterized in that in step 3, during from 0 to 90 millimeter of sliding platform (2) displacement, the translational speed of sliding platform 2 is 50 mm/min, and the displacement of sliding platform becomes 55 mm/min greater than translational speed after 90 millimeters.
4, method for founding aluminium alloy slab ingot according to claim 1, it is characterized in that in step 1, alloy raw material is heated to 740 ℃, the little progress row stirred and skimmed heating time, the mass percent of each element is controlled to be Si:0.60%, Fe:0.4%, Cu:0.15%, Mg:0.8%, Cr:0.04%, other single impurity≤0.05% in the alloy, other impurity add up to≤0.10%, and all the other are Al; Feed chlorine to the bottom of alloy liquation in step 2, the temperature that keeps the alloy liquation simultaneously melting 25 minutes between 700 ℃ was left standstill 15 minutes then.
5, method for founding aluminium alloy slab ingot according to claim 1, it is characterized in that in step 1, alloy raw material is heated to 760 ℃, heating the time is stirred and is skimmed, the mass percent of each element is controlled to be Si:0.8%, Fe:0.7%, Cu:0.40%, Mn:0.15%, Mg:1.2%, Cr:0.35%, Zn:0.25%, Ti:0.15%, other single impurity≤0.05% in the alloy, other impurity add up to≤0.10%, and all the other are Al; Feed chlorine to the bottom of alloy liquation in step 2, the temperature that keeps the alloy liquation simultaneously melting 35 minutes between 740 ℃ was left standstill 25 minutes then.
6, method for founding aluminium alloy slab ingot according to claim 1, it is characterized in that in step 1, alloy raw material being heated to 750 ℃, heating the time is stirred and is skimmed, the mass percent of each element is controlled to be Si:0.7%, Fe:0.55%, Cu:0.27%, Mn:0.075%, Mg:1.0%, Cr:0.20%, Zn:0.12%, Ti:0.075%, other single impurity≤0.05% in the alloy, other impurity add up to≤0.10%, and all the other are Al; Feed chlorine to the bottom of alloy liquation in step 2, the temperature that keeps the alloy liquation simultaneously melting 30 minutes between 740 ℃ was left standstill 20 minutes then.
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CN101708546B (en) * | 2009-11-27 | 2011-09-07 | 山东南山铝业股份有限公司 | Casting process of aluminum alloy slab ingot |
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CN100393451C (en) * | 2006-12-13 | 2008-06-11 | 中国铝业股份有限公司 | Casting process of 3140 flat aluminium alloy ingot |
CN100393450C (en) * | 2006-12-13 | 2008-06-11 | 中国铝业股份有限公司 | Low temperature casting process of 3140 flat aluminium alloy ingot |
CN100482828C (en) * | 2007-05-09 | 2009-04-29 | 东北轻合金有限责任公司 | High-accuracy aluminum alloy wave canal and manufacturing method thereof |
CN102181675A (en) * | 2011-04-09 | 2011-09-14 | 中信戴卡轮毂制造股份有限公司 | Process for preparing aluminum alloy slab ingot |
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CN1061913C (en) * | 1995-12-07 | 2001-02-14 | 鞍山市腾鳌特区合成金属材料有限公司 | Continuous aluminium-titanium-boron wire casting and extruding process |
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CN1061913C (en) * | 1995-12-07 | 2001-02-14 | 鞍山市腾鳌特区合成金属材料有限公司 | Continuous aluminium-titanium-boron wire casting and extruding process |
Non-Patent Citations (6)
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2A12铝合金扁锭皮下裂纹的工艺控制 孙兆霞,杨红,张仁伟,轻合金加工技术,第30卷第1期 2002;6061铝合金扁锭的裂纹及其预防措施 苏堪祥,邵正荣,郑宪,轻合金加工技术,第25卷第4期 1997;7075合金扁锭裂纹的工艺研究 吕新宇,吴欣凤,王立娟,铝加工,第25卷第2期 2002;LY12扁锭皮下裂纹的形成机理 王德满,苏堪祥,邵正荣,轻合金加工技术,第25卷第7期 1997;铝及软合金方锭多规格通用铸造工具的研究 付英祥,苏堪祥,轻合金加工技术,第25卷第6期 1997 * |
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7075合金扁锭裂纹的工艺研究 吕新宇,吴欣凤,王立娟,铝加工,第25卷第2期 2002 * |
LY12扁锭皮下裂纹的形成机理 王德满,苏堪祥,邵正荣,轻合金加工技术,第25卷第7期 1997 * |
铝及软合金方锭多规格通用铸造工具的研究 付英祥,苏堪祥,轻合金加工技术,第25卷第6期 1997 * |
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN101708546B (en) * | 2009-11-27 | 2011-09-07 | 山东南山铝业股份有限公司 | Casting process of aluminum alloy slab ingot |
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