CN1584085A - Alterant for overeutectic Al-Si alloy and its treatment - Google Patents
Alterant for overeutectic Al-Si alloy and its treatment Download PDFInfo
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Abstract
A modificator for hypereutectic alusil alloy consists of phosphorus 0.5-1.2wt%, titanium 3.5-6.0wt%, titanium carbide 8.0-12.0wt%, yttrium 0.05-0.30wt%, aluminum residue. The yttrium of rare earth element is substituted by 0.005-0.20lanthanum oxide , yttria or neodymium. It is used to be pressed into bulk, the adding volume is 0.5-3.0wt% of alloy smelt. It can be used to improve hardness and abrasion resistant performance.
Description
Technical field
The present invention relates to the rotten alterant of handling usefulness of molten alloy, particularly a kind of alterant and treatment process thereof that is used for refinement transcocrystallized Al-Si alloy primary silicon.
Background technology
Transcocrystallized Al-Si alloy has good fluidity, wear resistance height and the little characteristics of linear expansivity, is the ideal material of making wear parts such as motorcycle, automobile, tank; But the physical strength that does not have the rotten transcocrystallized Al-Si alloy of handling of process is very low, machinability is poor, surface smoothness is low: and big to the wearing and tearing of cutter, and working efficiency is also low, can not be in industrial direct application.Therefore, the primary silicon in the transcocrystallized Al-Si alloy just can make this type of alloy have application prospect after having only the process refinement.The general method that adds phosphorus that adopts is come the refinement primary silicon in industrial production, mainly is to add in red phosphorus, microcosmic salt or phosphorus-modes such as copper master alloy.But all there are many shortcomings in these methods: when rotten reaction violent, be easy to generate a large amount of smog, contaminate environment seriously, do not meet modern environmental requirement; Only join in the alloy as alterant with phosphorus-copper master alloy in addition, its modification effect is unstable again.Japan has developed the alterant of Al-Cu-P master alloy as transcocrystallized Al-Si alloy.Its preparation method is by the powder metallurgic method moulding, is squeezed into shaft-likely then, in semicontinuous water cooling casting process, under normal casting temp this alterant is being added in the chute continuously.Compare with other method that phosphorates, use the Al-Cu-P master alloy to have tangible advantage: (1) rate of recovery height, add-on is few; (2) instantaneous coming into force do not need the hold-time, can stay groove to add; (3) 730 ℃ of addings get final product, and melt must be not overheated; (4) modification effect is stable; (5) pollution-free.But this master alloy manufacturing process complexity, the production cost height has been applied certain difficulty.The Al-P master alloy of domestic development can solve problem of environmental pollution, improves work situation greatly.Go bad when handling with the Al-P master alloy, its interpolation process and alloying process are synchronous fully, not only reduce the work degree greatly, shorten smelting time, enhance productivity, and modification effect are good, stablize.But in fact, the primary silicon grain-size average out to 30-40 μ m of this kind method refinement, its modification effect is unsatisfactory.
Transcocrystallized Al-Si alloy fining modifier commonly used both at home and abroad at present mostly is red phosphorus, phosphorated compound or rare earth etc.Adopt red phosphorus, phosphorated compound or rare earth to come the refinement primary silicon as alterant separately, its modification effect can not be brought into play fully.Therefore, often adopt composite inoculating to handle to transcocrystallized Al-Si alloy.Table 1 has provided the thinning effect of the domestic and international at present alterant of having developed to primary silicon in the transcocrystallized Al-Si alloy.
Table 1
Alterant
Primary silicon in the transcocrystallized Al-Si alloy
Primary silicon before rotten
Rotten back primary silicon
Composition
Content (%)
Mean sizes (μ m) mean sizes (μ m)
Phosphor-copper, RE multiple modification 18 150 26
Cerium, phosphorus compound modifier 20 150 20~25
Aluminium, phosphorus master alloy 20 90 30
Microcosmic salt, lithium salts, antimony, aluminium, titanium, 21.5~23 250 35
The boron compound modifier
Rare earth, aluminium, titanium, boron, phosphorus multiple 22~24 250 26~33
Close alterant
Aluminium, phosphorus master alloy 24 120 40
Summary of the invention
The alterant that the purpose of this invention is to provide a kind of novel transcocrystallized Al-Si alloy can make further refinement of primary silicon in the transcocrystallized Al-Si alloy, thereby improves the alloy use properties.
The present invention is used for the alterant of transcocrystallized Al-Si alloy, is made up of by weight percentage following element: phosphorus: 0.5~1.2, and titanium: 3.5~6.0, titanium carbide: 8.0~12.0, yttrium: 0.05~0.30, surplus is an aluminium.
Rare earth element yttrium wherein also can be substituted by rare earth oxide, form by following weight percent: phosphorus: 0.5~1.2, titanium: 3.5~6.0, titanium carbide: 8.0~12.0, lanthanum sesquioxide or yttrium oxide or neodymium sesquioxide: 0.005~0.20, surplus is an aluminium.
With the metamorphism treatment method of above-mentioned alterant, carry out according to the following steps: the alterant of preparation is pressed into bulk the melting transcocrystallized Al-Si alloy; After alloy melts in electrical crucible, carry out the refining agent degasification at 820-850 ℃, and under this temperature, leave standstill 5~10 minutes; Add above-mentioned block alterant down at 750-850 ℃, the weight percent that its alterant add-on accounts for alloy melt is 0.5-3.0.Left standstill after the stirring 5-15 minute; At 730-850 ℃ of casting.
Adopt alterant of the present invention, can make the silicon content weight percent is that primary silicon refine to 8~25 μ m in 13~31 the transcocrystallized Al-Si alloy.Through the transcocrystallized Al-Si alloy that this alterant is handled, its processing characteristics and surface smoothness obviously improve, and have significantly reduced the wearing and tearing of cutter, and hardness and wear resistance obviously improve simultaneously.Enlarged the application of transcocrystallized Al-Si alloy in fields such as Aeronautics and Astronautics, military project, automobile, motorcycles.
The preparation technology of alterant of the present invention is simple, and is easy to operate; Compare with traditional alterant, little to the pollution of environment.
Description of drawings
Fig. 1 is that the silicon content weight percent is 17 the aluminum silicon alloy metallographic structure picture when rotten;
Fig. 2 is that the silicon content weight percent is 17 the metallographic structure picture of aluminum silicon alloy after the rotten processing of aluminium powder-phosphorus-titanium-titanium carbide-yttrium;
Fig. 3 is that the silicon content weight percent is 20 the aluminum silicon alloy metallographic structure picture when rotten;
Fig. 4 is that the silicon content weight percent is 20 the metallographic structure picture of aluminum silicon alloy after the rotten processing of aluminium powder-phosphorus-titanium-titanium carbide-yttrium;
Fig. 5 is that the silicon content weight percent is 29 the aluminum silicon alloy metallographic structure picture when rotten;
Fig. 6 is that the silicon content weight percent is 29 the metallographic structure picture of aluminum silicon alloy after the rotten processing of aluminium powder-phosphorus-titanium-titanium carbide-yttrium;
Shown in Figure 7 is that the silicon content weight percent is that 20 aluminum silicon alloy does not have the metallographic structure after rotten the processing:
Fig. 8 is that the silicon content weight percent is 20 the metallographic structure picture of aluminum silicon alloy after the rotten processing of aluminium powder-phosphorus-titanium-titanium carbide-lanthanum sesquioxide;
Fig. 9 is that the silicon content weight percent is 20 the metallographic structure picture of aluminum silicon alloy after the rotten processing of aluminium powder-phosphorus-titanium-titanium carbide-yttrium oxide;
Figure 10 is that the silicon content weight percent is 20 the metallographic structure picture of aluminum silicon alloy after the rotten processing of aluminium powder-phosphorus-titanium-titanium carbide-neodymium sesquioxide:
Figure 11 is that (composition consists of alterant: P 0.5, Ti 3.5, TiC 8.0, La
2O
30.01, all the other are aluminium) add-on is to the influence curve figure of primary silicon mean sizes in the alloy;
Figure 12 is that (composition consists of alterant: P 0.5, Ti 3.5, TiC 8.0, Y
2O
30.1, all the other are aluminium) add-on is to the influence curve figure of primary silicon mean sizes in the alloy;
Figure 13 is that (composition consists of alterant: P 0.5, Ti 3.5, TiC 8.0, Nd
2O
3: 0.1, all the other are aluminium) add-on is to the influence curve figure of primary silicon mean sizes in the alloy;
Figure 14 be rotten before and after the silicon content weight percent be that 20 aluminum silicon alloy and silicon content are 29 aluminum silicon alloy abrasive wear curve;
Table 1 is the thinning effect of the domestic and international at present alterant of having developed to primary silicon in the transcocrystallized Al-Si alloy;
Table 2 is Brinell hardness numbers of rotten front and back transcocrystallized Al-Si alloy.
Embodiment
Embodiment 1:
Preparation by weight percentage, the weight percent composition of alterant is chosen as P:0.5, Ti:3.5, TiC:8.0, Y:0.05, all the other are aluminium.Raw material is prepared in proportion also and is pressed into bulk behind the uniform mixing.
The weight percent selection of chemical composition of transcocrystallized Al-Si alloy is as follows:
Si:17, Cu:4.8, Mg:0.64, Fe:0.81, Mn:0.20, all the other are aluminium.
After alloy melts, about 850 ℃, carry out the refining agent degasification in electrical crucible, and under this temperature, left standstill 5~10 minutes; Add alterant, the weight percent that the alterant add-on accounts for alloy melt is 0.4; Left standstill after the stirring 10 minutes; Pour into a mould sample down at 850 ℃.Fig. 1 and Fig. 2 are respectively the metallographic structures of rotten preceding and rotten back alloy.Shown in Figure 1 is that siliceous weight percent is the metallographic structure when rotten of 17 aluminum silicon alloy, and the mean sizes of primary silicon can reach 100 μ m as seen from the figure; Shown in Figure 2 is that siliceous weight percent is 17 the metallographic structure of aluminum silicon alloy after rotten the processing, and the size of primary silicon can reach 8~18 μ m as seen from the figure.The hardness of transcocrystallized Al-Si alloy is as shown in table 2 before and after rotten, siliceous weight percent be 17 aluminum silicon alloy after rotten the processing, its Brinell hardness number is 20 than the per-cent of raising before rotten.
Table 2
Brinell hardness number (HB) after Brinell hardness number (HB) before material is rotten is rotten
The alloy 110.0 132.0 that embodiment 1 adopts
The alloy 83.0 96.1 that embodiment 2 adopts
The alloy 97.7 120.0 that embodiment 3 adopts
The alloy 127 145 that embodiment 4 adopts
The alloy 127 154 that embodiment 5 adopts
The alloy 127 145 that embodiment 6 adopts
Embodiment 2:
Preparation by weight percentage, the weight percent of alterant composition is chosen as P:0.7, Ti:4.0, TiC:8.5, Y:0.08, all the other are aluminium.Raw material is prepared in proportion also and is pressed into bulk behind the uniform mixing.
The selection of chemical composition of transcocrystallized Al-Si alloy weight percent is as follows:
Si:20, Cu:0.78, Mg:0.35, Fe:0.76, Mn:0.28, all the other are aluminium.
After alloy melts, about 850 ℃, carry out the refining degasification in electrical crucible, and under this temperature, left standstill 5~10 minutes; Add alterant, the per-cent that the alterant add-on accounts for alloy liquid weight is 0.5; Left standstill after the stirring 10 minutes; Pour into a mould sample down at 830 ℃.Fig. 3 and Fig. 4 are respectively the metallographic structures of rotten preceding and rotten back alloy.Shown in Figure 3 is that the silicon content weight percent is the metallographic structure when rotten of 20 aluminum silicon alloy, and the size of primary silicon can reach 200 μ m as seen from the figure; Shown in Figure 4 is that the silicon content weight percent is 20 the metallographic structure of aluminum silicon alloy after rotten the processing, and the size of primary silicon can reach 15~20 μ m as seen from the figure.Figure 14 is the abrasive wear curve of rotten front and back aluminum silicon alloy.As can be seen from the figure, the wear resistance of alloy obviously improves before going bad after rotten the processing.Experimental result shows: respectively under 0.3 kilogram, 0.5 kilogram, 0.7 kilogram, 0.9 kilogram four kinds of different load, the silicon content weight percent be 20 aluminum silicon alloy after rotten the processing, the per-cent that improves respectively before its wear resistance is rotten is 110,104,105 and 106.The hardness of transcocrystallized Al-Si alloy is as shown in table 2 before and after rotten, the silicon content weight percent be 20 aluminum silicon alloy after rotten the processing, its Brinell hardness number is 15.8 than the per-cent of raising before rotten.
Embodiment 3:
Preparation by weight percentage, the weight percent composition of alterant is chosen as P:1.1, Ti:5.5, TiC:11.0, Y:0.15, all the other are aluminium.Raw material is prepared in proportion also and is pressed into bulk behind the uniform mixing.
The selection of chemical composition of transcocrystallized Al-Si alloy weight percent is as follows:
Si:29, Cu:0.58, Mg:0.18, Fe:0.82, Mn:0.26, all the other are aluminium.
After alloy melts, about 850 ℃, carry out the refining agent degasification in electrical crucible, and under this temperature, left standstill 5~10 minutes; Add alterant, the weight percent that the alterant add-on accounts for alloy melt is 2.5; Left standstill after the stirring 10 minutes; Pour into a mould sample down at 850 ℃.Fig. 5 and Fig. 6 are respectively the metallographic structures of rotten preceding and rotten back alloy.Shown in Figure 5 is that the silicon content weight percent is the metallographic structure when rotten of 29 aluminum silicon alloy, and the size of primary silicon can reach 100~350 μ m as seen from the figure; Shown in Figure 6 is that the silicon content weight percent is 29 the metallographic structure of aluminum silicon alloy after rotten the processing, and the size of primary silicon can reach 25~35 μ m as seen from the figure.Figure 14 is the abrasive wear curve of rotten front and back aluminum silicon alloy.As can be seen from the figure, the wear resistance of alloy obviously improves before going bad after rotten the processing.Experimental result shows: respectively under 0.3 kilogram, 0.5 kilogram, 0.7 kilogram, 0.9 kilogram four kinds of different load, the silicon content weight percent be 29 aluminum silicon alloy after rotten the processing, the per-cent that improves respectively before its wear resistance is rotten is 128,114,112 and 116.The hardness of transcocrystallized Al-Si alloy is as shown in table 2 before and after rotten, the silicon content weight percent be 29 aluminum silicon alloy after rotten the processing, its Brinell hardness number is 32 than the per-cent of raising before rotten.
Embodiment 4:
Preparation by weight percentage, the weight percent composition of alterant is chosen as P:0.5, Ti:3.5, TiC:8.0, La
2O
3: 0.01, all the other are aluminium.Raw material is prepared in proportion also and is pressed into bulk behind the uniform mixing.
The weight percent selection of chemical composition of transcocrystallized Al-Si alloy is as follows:
Si:20, Cu:4.7, Mg:0.58, Fe:0.88, Mn:0.20, all the other are aluminium.
After alloy melts, about 850 ℃, carry out the refining degasification in electrical crucible, and under this temperature, left standstill 5~10 minutes; Add aluminium powder-phosphorus-titanium-titanium carbide-lanthanum sesquioxide alterant, the weight percent that the alterant add-on accounts for alloy melt is respectively 0.5,1.0,3.0; Left standstill after the stirring 10 minutes; Pour into a mould sample down at 850 ℃.Fig. 7 and Fig. 8 are respectively the metallographic structures of rotten preceding and rotten back alloy.Shown in Figure 7 is that silicon content is the metallographic structure when rotten of 20 aluminum silicon alloy, and the mean sizes of primary silicon can reach 150 μ m as seen from the figure; Shown in Figure 8 is that silicon content is 20 the metallographic structure of aluminum silicon alloy after rotten the processing.Different alterant add-ons to the influence of primary silicon mean sizes in this alloy as shown in figure 11.The hardness of transcocrystallized Al-Si alloy is as shown in table 2 before and after rotten, silicon content be 20 aluminum silicon alloy after rotten the processing, its Brinell hardness number is 14.2 than the per-cent of raising before rotten
Embodiment 5:
Preparation by weight percentage, the composition of alterant is chosen as P:0.5, Ti:3.5, TiC:8.0, Y
2O
3: 0.1, all the other are aluminium.Raw material is prepared in proportion also and is pressed into bulk behind the uniform mixing.
The weight percent selection of chemical composition of transcocrystallized Al-Si alloy is as follows:
Si:20, Cu:4.7, Mg:0.58, Fe:0.88, Mn:0.20, all the other are aluminium.
After alloy melts, about 850 ℃, carry out the refining agent degasification in electrical crucible, and under this temperature, left standstill 5~10 minutes; Add aluminium powder-phosphorus-titanium-titanium carbide-yttrium oxide alterant, the weight percent that the alterant add-on accounts for alloy melt is respectively 0.5,1.0,3.0: left standstill after the stirring 10 minutes; Pour into a mould sample down at 850 ℃.Fig. 9 and Figure 10 are respectively the metallographic structures of rotten preceding and rotten back alloy.Shown in Figure 9 is that silicon content is the metallographic structure when rotten of 20 aluminum silicon alloy, and the mean sizes of primary silicon can reach 150 μ m as seen from the figure; Shown in Figure 10 is that silicon content is 20 the metallographic structure of aluminum silicon alloy after rotten the processing.Different alterant add-ons to the influence of primary silicon mean sizes in this alloy as shown in figure 12.The hardness of transcocrystallized Al-Si alloy is as shown in table 2 before and after rotten, silicon content be 20 aluminum silicon alloy after rotten the processing, its Brinell hardness number is 21.3 than the per-cent of raising before rotten.
Embodiment 6:
Preparation by weight percentage, the composition of alterant is chosen as P:0.5, Ti:3.5, TiC:8.0, Nd
2O
3: 0.1, all the other are aluminium.Raw material is prepared in proportion also and is pressed into bulk behind the uniform mixing.
The selection of chemical composition of transcocrystallized Al-Si alloy is as follows:
Si:20, Cu:4.7, Mg:0.58, Fe:0.8, Mn:0.20, all the other are aluminium.
After alloy melts, about 850 ℃, carry out the refining degasification in electrical crucible, and under this temperature, left standstill 5~10 minutes; Add aluminium powder-phosphorus-titanium-titanium carbide-neodymium sesquioxide alterant, the weight percent that the alterant add-on accounts for alloy melt is respectively 0.5,1.0,3.0; Left standstill after the stirring 10 minutes; Pour into a mould sample down at 850 ℃.Figure 11 and Figure 12 are respectively the metallographic structures of rotten preceding and rotten back alloy.Shown in Figure 11 is that silicon content is the metallographic structure when rotten of 20 aluminum silicon alloy, and the mean sizes of primary silicon can reach 150 μ m as seen from the figure; Shown in Figure 12 is that silicon content is 20 the metallographic structure of aluminum silicon alloy after rotten the processing.Different alterant add-ons to the influence of primary silicon mean sizes in this alloy as shown in figure 13.The hardness of transcocrystallized Al-Si alloy is as shown in table 2 before and after rotten, silicon content be 20 aluminum silicon alloy after rotten the processing, its Brinell hardness number is 14.2 than the per-cent of raising before rotten.
Claims (3)
1. alterant that is used for transcocrystallized Al-Si alloy is characterized in that being made up of by weight percentage following element: phosphorus: 0.5~1.2, and titanium: 3.5~6.0, titanium carbide: 8.0~12.0, yttrium: 0.05~0.30, surplus is an aluminium.
2. alterant that is used for transcocrystallized Al-Si alloy, it is characterized in that forming by weight percentage: phosphorus by following element: 0.5~1.2, titanium: 3.5~6.0, titanium carbide: 8.0~12.0, lanthanum sesquioxide or yttrium oxide or neodymium sesquioxide: 0.005~0.20, surplus is an aluminium.
3. with claim 1,3 described alterants metamorphism treatment method, carry out according to the following steps: the alterant of preparation is pressed into bulk the melting transcocrystallized Al-Si alloy; After alloy melts in electrical crucible, carry out the refining agent degasification at 820-850 ℃, and under this temperature, leave standstill 5~10 minutes; Add above-mentioned block alterant down at 750-850 ℃, its alterant add-on is the 0.5-3.0% of alloy melt weight.Left standstill after the stirring 5-15 minute; At 730-850 ℃ of casting.
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Cited By (11)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN100436615C (en) * | 2007-05-26 | 2008-11-26 | 太原理工大学 | Aluminum-titanium-carbon-yttrium intermediate alloy and preparing method thereof |
| CN100532597C (en) * | 2007-12-20 | 2009-08-26 | 中国铝业股份有限公司 | Phosphor alterative for hypereutectic aluminum-silicon alloy |
| CN102586634A (en) * | 2011-11-27 | 2012-07-18 | 吉林大学 | Aluminium-silicon alloy modifier and treatment method thereof |
| CN103831422A (en) * | 2012-11-27 | 2014-06-04 | 中国兵器科学研究院宁波分院 | Nanometer refining method of Al-Si system aluminum alloy structure |
| CN105861889A (en) * | 2016-05-18 | 2016-08-17 | 安徽省安庆市金誉金属材料有限公司 | High-strength wear-resistant aluminum alloy |
| CN106756151A (en) * | 2016-12-16 | 2017-05-31 | 镇江创智特种合金科技发展有限公司 | A kind of method of the rotten AlSiCu alloys of rare earth Er |
| CN107400808A (en) * | 2017-08-10 | 2017-11-28 | 兰州理工大学 | A kind of Al Ti C Nb intermediate alloys and its preparation method and application |
| CN108315576A (en) * | 2018-01-12 | 2018-07-24 | 秦皇岛兴龙轮毂有限公司 | A kind of efficient alterant of A356 aluminium alloys and preparation method |
| CN108754195A (en) * | 2018-06-29 | 2018-11-06 | 张家港江苏科技大学产业技术研究院 | A kind of alterant and preparation method thereof to go bad for Fe-riched phase in hypereutectic high ferro alusil alloy |
| CN110438358A (en) * | 2019-08-20 | 2019-11-12 | 南昌大学 | A kind of composite modifier and preparation method for hypereutectic al-si copper alloy |
| CN116970831A (en) * | 2023-09-13 | 2023-10-31 | 四川航天职业技术学院(四川航天高级技工学校) | Refining method of high-silicon aluminum alloy |
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2004
- 2004-06-11 CN CN 200410010911 patent/CN1281774C/en not_active Expired - Fee Related
Cited By (13)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN100436615C (en) * | 2007-05-26 | 2008-11-26 | 太原理工大学 | Aluminum-titanium-carbon-yttrium intermediate alloy and preparing method thereof |
| CN100532597C (en) * | 2007-12-20 | 2009-08-26 | 中国铝业股份有限公司 | Phosphor alterative for hypereutectic aluminum-silicon alloy |
| CN102586634A (en) * | 2011-11-27 | 2012-07-18 | 吉林大学 | Aluminium-silicon alloy modifier and treatment method thereof |
| CN103831422A (en) * | 2012-11-27 | 2014-06-04 | 中国兵器科学研究院宁波分院 | Nanometer refining method of Al-Si system aluminum alloy structure |
| CN103831422B (en) * | 2012-11-27 | 2016-03-02 | 中国兵器科学研究院宁波分院 | A kind of nanometer thinning method of Al-Si line aluminium alloy tissue |
| CN105861889A (en) * | 2016-05-18 | 2016-08-17 | 安徽省安庆市金誉金属材料有限公司 | High-strength wear-resistant aluminum alloy |
| CN106756151A (en) * | 2016-12-16 | 2017-05-31 | 镇江创智特种合金科技发展有限公司 | A kind of method of the rotten AlSiCu alloys of rare earth Er |
| CN107400808A (en) * | 2017-08-10 | 2017-11-28 | 兰州理工大学 | A kind of Al Ti C Nb intermediate alloys and its preparation method and application |
| CN107400808B (en) * | 2017-08-10 | 2019-03-29 | 兰州理工大学 | A kind of Al-Ti-C-Nd intermediate alloy and its preparation method and application |
| CN108315576A (en) * | 2018-01-12 | 2018-07-24 | 秦皇岛兴龙轮毂有限公司 | A kind of efficient alterant of A356 aluminium alloys and preparation method |
| CN108754195A (en) * | 2018-06-29 | 2018-11-06 | 张家港江苏科技大学产业技术研究院 | A kind of alterant and preparation method thereof to go bad for Fe-riched phase in hypereutectic high ferro alusil alloy |
| CN110438358A (en) * | 2019-08-20 | 2019-11-12 | 南昌大学 | A kind of composite modifier and preparation method for hypereutectic al-si copper alloy |
| CN116970831A (en) * | 2023-09-13 | 2023-10-31 | 四川航天职业技术学院(四川航天高级技工学校) | Refining method of high-silicon aluminum alloy |
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| Publication number | Publication date |
|---|---|
| CN1281774C (en) | 2006-10-25 |
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