CN1438347A - Metal-base composite material reinforced by metal alternate compound granule containing rare-earth element - Google Patents
Metal-base composite material reinforced by metal alternate compound granule containing rare-earth element Download PDFInfo
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- CN1438347A CN1438347A CN 03119684 CN03119684A CN1438347A CN 1438347 A CN1438347 A CN 1438347A CN 03119684 CN03119684 CN 03119684 CN 03119684 A CN03119684 A CN 03119684A CN 1438347 A CN1438347 A CN 1438347A
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Abstract
The invention discloses a kind of metalmetallic compound particle reinforcing metal group compound material which contains rare earth, it includes reinforcing body and group alloy, the reinforcing body accounts for about 5-45% of total volume, the remnant is group alloy, the reinforcing body is YA1 series, CeAl series, LaAl serial metalmetallic compound particle, the group alloy is Mg and Mg alloy.
Description
Technical field
The present invention relates to a kind of compound particle enhancing metal-base composites between rare earth elemental metals that contains.This matrix material has higher modulus of elasticity and rigidity, and good plasticity is easy to moulding and machinery reprocessing.
Background technology
Mg-Li base alloy is because of having low density (1.35~1.65g/cm
3), higher specific tenacity and specific rigidity, good damping performance and the penetrativity of anti-high energy particle, as the lightest structural metallic material in the nontoxic metallic substance, wide application prospect is arranged in fields such as aerospace, communications and transportation.In binary Mg-Li alloy, increase along with the Li amount, α (hcp) → alpha+beta → β (bcc) is taking place and is changing (as shown in Figure 1) in alloy structure, the plastic deformation ability of alloy is significantly improved, its unit elongation can reach more than 40%, but because alloy strength is on the low side, creep-resistant property is relatively poor, has limited Mg-Li base alloy range of application.
Mg-Li base complex intensifying then provides effective way for the mechanical property that further improves the Mg-Li alloy.Compare with the Mg-Li matrix alloy, matrix material has not only kept conduction, heat conduction and the good hot and cold processing characteristics of matrix alloy, and integrate low density, high specific stiffness, high specific strength, good wear resistance, resistance to elevated temperatures, damping performance and good damping performance and capability of electromagnetic shielding, become one of focus of investigation of materials.As other matrix material, the enhancing mode of Mg based composites also mainly contains fiber reinforcement, particle strengthens and whisker strengthens three kinds of modes, and enhancing ingredients mainly contains SiC, B
4C, Al
2O
3, the borate of TiC, graphite, glass fibre, aluminium or ceramic fibre etc.These strengthen bodies and both can adopt with particle, fiber or whisker form and add separately, also can adopt mixed form (SiC particle/Al for example
2O
3Whisker mixes) add and strengthen, and improved the mechanical property of alloy to some extent.But the stupalith complex intensifying has also brought the plasticity of material and the problem of toughness major injury.From result of study, Mg-Li matrix alloy and ceramic reinforcing material have good wettability and chemical compatibility can form the comparatively compound phase interface of ideal, so the plasticity of material and flexible descend closely related with the fragility of ceramic enhancement phase significantly.Therefore, choose the material that not only has enhancement but also possess certain microstrain coordinative role, the over-all properties of improving material is had great significance as Mg based composites strongthener.
Intermetallic compound is because of having the characteristic of metal, as show metalluster, metallic conductivity and thermal conductivity etc., thereby select the wild phase of intermetallic compound particle as metal-base composites, easier obtaining has adaptive interfaces such as good wettability, chemical compatibility with metallic matrix.And intermetallic compound had than high specific strength and specific rigidity, and the high use temperature between alloy and pottery, made it become the effective wild phase of alloy.Intermetallic compound has good plasticity-with respect to pottery, thereby it damages less than the damage of adopting ceramic enhancement phase to cause the plasticity of alloy substrate when improving matrix alloy intensity.The above provides the foundation for formation intermetallic compound particle enhancing metal-base composites has good comprehensive performances.
Summary of the invention
Compound particle strengthens metal-base composites between rare earth elemental metals to the purpose of this invention is to provide a kind of novel containing.This matrix material has higher modulus of elasticity and rigidity, good plasticity, be easy to moulding and machinery reprocessing, combining high strength, high rigidity, ceramic excellent plasticity and good machinability, rigidity and the processability that metallic matrix had as the intermetallic compound of enhanced granule, is that a kind of light-duty intermetallic compound particle strengthens metal-base composites.
For achieving the above object, the present invention is by the following technical solutions:
A kind of compound particle that contains between rare earth elemental metals strengthens metal-base composites, it by strengthen body, matrix alloy is formed.It strengthens body and accounts for 5~45% of cumulative volume, and surplus is a matrix alloy, and described enhancing body is the intermetallic compound particle that contains rare earth element, and described matrix alloy is the Mg alloy.It strengthens body can be YAl series intermetallic compound particle, its Al content 13.17~47.66wt%, and more excellent is YAl
2Intermetallic compound particle; It strengthens body can be CeAl series intermetallic compound particle, its Al content 14.35~43.51wt%, and more excellent is CeAl
2Intermetallic compound particle; It strengthens body can be LaAl series intermetallic compound particle, its Al content 6.08~43.72wt%, and more excellent is LaAl
2Intermetallic compound particle.
Described matrix alloy can be the Mg-Li alloy, its Li content 0~20wt%.
The present invention has used high specific strength that intermetallic alloy has, specific rigidity and than the plasticity-of stupalith excellence and limited the characteristics such as room temperature fragility that the intermetallic compound bulk is used, and preparation contains that compound particle strengthens metal-base composites between rare earth elemental metals.
Fig. 1 is a binary Mg-Li phasor.
Embodiment
A kind of compound particle enhancing metal-base composites between rare earth elemental metals that contains of the present invention can prepare its matrix material by casting, pressure method of impregnation, powder (or film) metallurgy method.In the following embodiments, the contriver only enumerates with casting method and is prepared explanation.
Fusion casting is meant and melts matrix alloy at a certain temperature, add behind the reinforced particulate then and be cooled to half curdled appearance, under this state, stir the alloy melt certain hour, make to strengthen the body even particle distribution, elevated temperature is to pouring temperature then, cast molding rapidly.Fusion process adopts argon shield.
The present invention is a kind of compound particle enhancing metal-base composites between rare earth elemental metals that contains, it is formed by strengthening body and matrix alloy, it strengthens body and accounts for 5~45% of cumulative volume, surplus is a matrix alloy, described enhancing body is the intermetallic compound particle that contains rare earth element, and described matrix alloy is the Mg alloy.
Matrix material with preparation weight 1Kg is an example.
Embodiment 1:
YAl series intermetallic compound particle strengthens the Mg-11wt%Li based composites
YAl series intermetallic compound granule preparing process:
According to Al content 13.17~47.66wt%, remain alloy raw material into Y proportioning YAl, founding YAl intermetallic compound block materials prepares required intermetallic compound particle by general milling after the mechanical disintegration under 900~1530 ℃ of temperature.
The YAl that adds 20% (volume content) in Mg-11wt%Li alloy liquation is a particle, and the particle median size is about 5~50 μ m.The founding condition is as follows: is cooled to 580 ℃ behind 595 ℃ of adding reinforced particulates, under half curdled appearance, stirs the about 10min of alloy melt, make even particle distribution, and elevated temperature to 630 ℃ casting rapidly then, fusion process adopts argon shield.The composite materials property test result shows, alloy is under the little situation of plasticity damage, and unit elongation minimumly reduces to 20~25% by 30% of matrix alloy, and shearing resistance is increased to 130~165MPa by 95MPa, and intensity level improves more than 30%.
YAl
2Intermetallic compound particle strengthens the Mg-11wt%Li based composites
According to Al content 37.76wt%, remain alloy raw material, founding YAl under 1530 ℃ of temperature into Y proportioning YAl
2The intermetallic compound block materials prepares required intermetallic compound particle by general milling after the mechanical disintegration.
The YAl that in Mg-11wt%Li alloy liquation, adds 20% (volume content)
2Particle, particle median size are about 10 μ m.The founding condition is as follows: is cooled to 580 ℃ behind 595 ℃ of adding reinforced particulates, under half curdled appearance, stirs the about 10min of alloy melt, make even particle distribution, and elevated temperature to 630 ℃ casting rapidly then, fusion process adopts argon shield.The composite materials property test result shows that alloy is under the little situation of plasticity damage, and unit elongation reduces to 22% by 30% of matrix alloy, and shearing resistance is increased to 165MPa by 95MPa, and intensity level improves more than 30%.
Adopt the YAl series intermetallic compound to have higher specific tenacity and specific rigidity, can be used as strongthener and effectively strengthen Mg-Li base alloy; With the ceramic phase ratio, based on intermetallic, and pottery is based on covalent linkage from the angle YAl series intermetallic compound of bonding action, so YAl series intermetallic compound particle and metallic matrix may have better wettability.Simultaneously, intermetallic compound Y, Al elemental diffusion will help improving the associativity of reinforced particulate and metallic matrix; The Al elemental diffusion will further improve the intensity of alloy, and the diffusion of Y rare earth element will help refinement and rotten tissue, improve the mechanical property of alloy and alloy is anti-oxidant and creep property; The more important thing is, intermetallic compound has much higher plasticity-than stupalith, intermetallic compound particle is used to strengthen metal-base composites, help improving the Harmony of enhanced granule and basal body interface deformation under the texturizing condition, with the retardation of raising material crack crack initiation and expansion, thereby on improving, material obdurability over-all properties has than remarkable advantages.The room temperature fragility of intermetallic compound bulk is the problem that influences alloy practicability always, yet this character but provides favourable condition for the powder process of particulate reinforced composite, by common ball milling, can obtain uniform powder, provide convenience for obtaining strongthener.The Application Areas of intermetallic compound has been expanded in this invention, and provides a new approach for the preparation of matrix material.
Rare earth element is typical metallic element.Their metal activity is only second to basic metal and alkali earth metal, and more active than other metallic elements.In the middle of 17 rare earth elements, press the active order of metal and arrange, by Sc (scandium), Y (yttrium), La (lanthanum) increase progressively, and are successively decreased to Lu (lutetium) by La (lanthanum), and promptly La (lanthanum) element is the most active.Rare earth element can form chemically stable oxide compound, halogenide, sulfide.Rare earth element can react with nitrogen, hydrogen, carbon, phosphorus, is soluble in hydrochloric acid, sulfuric acid and the nitric acid.
The part physical property such as the following table of La (lanthanum), Ce (cerium), three kinds of rare earth elemental metals of Y (yttrium):
| Element | Ordination number | Nucleidic mass | Ionic radius (dust) | Density (g/cm 3) | Fusing point (℃) | Boiling point (℃) | The oxide compound fusing point (℃) | Than resistance (ohmcm * 10 6) | ??R 3+Ion magnetic moment (Bohr magnetron) | Thermal-neutron capture cross-section (target) |
| ??La | ??57 | ??138.92 | ??1.22 | ??6.19 | ??920±5 | ??4230 | ??2315 | ??56.8 | ??0.00 | ??8.9 |
| ??Ce | ??58 | ??140.13 | ??1.18 | ??6.768 | ??804±5 | ??2930 | ??1950 | ??75.3 | ??2.56 | ??0.7 |
| ??Y | ??39 | ??88.92 | ??1.06 | ??4.472 | ??1550~ ??1600 | ??3030 | ??2680 | ??- | ??- | ??1.27 |
Embodiment 2:
CeAl series intermetallic compound particle strengthens the Mg-13wt%Li based composites
CeAl series intermetallic compound granule preparing process:
According to Al content 14.35~43.51wt%, remain alloy raw material into Ce proportioning CeAl, founding CeAl intermetallic compound block materials prepares required intermetallic compound particle by general milling after the mechanical disintegration under 900~1500 ℃ of temperature.
The CeAl series intermetallic compound particle that adds 30% (volume content) in Mg-13wt%Li alloy liquation, particle median size are about 5~50 μ m.The founding condition is as follows: is cooled to 570 ℃ behind 590 ℃ of adding reinforced particulates, under half curdled appearance, stirs the about 10min of alloy melt, make even particle distribution, and elevated temperature to 620 ℃ casting rapidly then, fusion process adopts argon shield.The composite materials property test result shows, alloy is under the little situation of plasticity damage, and unit elongation minimumly reduces to 20~30% by 35% of matrix alloy, and shearing resistance is increased to 100~140Mpa by 82Mpa, and intensity level improves more than 20%.
CeAl
2Intermetallic compound particle strengthens the Mg-13wt%Li based composites
According to Al content 27.78wt%, remain alloy raw material into Ce proportioning CeAl, founding CeAl2 intermetallic compound block materials prepares required intermetallic compound particle by general milling after the mechanical disintegration under 1500 ℃ of temperature.
The CeAl that in Mg-13wt%Li alloy liquation, adds 30% (volume content)
2Particle, particle median size are about 20 μ m.The founding condition is as follows: is cooled to 570 ℃ behind 590 ℃ of adding reinforced particulates, under half curdled appearance, stirs the about 10min of alloy melt, make even particle distribution, and elevated temperature to 620 ℃ casting rapidly then, fusion process adopts argon shield.The composite materials property test result shows that alloy is under the little situation of plasticity damage, and unit elongation reduces to 24% by 35% of matrix alloy, and shearing resistance is increased to 122Mpa by 82Mpa, and intensity level improves more than 40%.
Embodiment 3:
LaAl series intermetallic compound particle strengthens the Mg-8wt%Li based composites
According to Al content 6.08~43.72wt%, remain alloy raw material into La proportioning LaAl, founding LaAl intermetallic compound block materials prepares required intermetallic compound particle by general milling after the mechanical disintegration under 800~1450 ℃ of temperature.
The LaAl series intermetallic compound particle that adds 15% (volume content) in Mg-8wt%Li alloy liquation, particle median size are about 5~50 μ m.The founding condition is as follows: is cooled to 580 ℃ behind 600 ℃ of adding reinforced particulates, under half curdled appearance, stirs the about 10min of alloy melt, make even particle distribution, and elevated temperature to 630 ℃ casting rapidly then, fusion process adopts argon shield.The composite materials property test result shows that alloy is under the little situation of plasticity damage, and unit elongation reduces to 8~14% by 15% of matrix alloy, and shearing resistance is increased to 120~160Mpa by 100Mpa, and intensity level improves more than 20%.
LaAl
2Intermetallic compound particle strengthens the Mg-8wt%Li based composites
According to A1 content 27.98wt%, remain alloy raw material into La proportioning LaAl, founding LaAl2 intermetallic compound block materials prepares required intermetallic compound particle by general milling after the mechanical disintegration under 1450 ℃ of temperature.
The LaAl that in Mg-8wt%Li alloy liquation, adds 15% (volume content)
2Particle, particle median size are about 15 μ m.The founding condition is as follows: is cooled to 580 ℃ behind 600 ℃ of adding reinforced particulates, under half curdled appearance, stirs the about 10min of alloy melt, make even particle distribution, and elevated temperature to 630 ℃ casting rapidly then, fusion process adopts argon shield.The composite materials property test result shows that alloy is under the little situation of plasticity damage, and unit elongation reduces to 11% by 15% of matrix alloy, and shearing resistance is increased to 140Mpa by 100Mpa, and intensity level improves more than 40%.
This composite property excellence can be used widely in fields such as aerospace, communications and transportation.As can be used for preparing antenna structure, and make the framework and the shell of computer, electrical instrumentation etc., make the protective shield of car, preceding seat support, wheel hub etc.Magnesium lithium based composites apply the weight that can alleviate aircraft, automobile etc., thereby reach effect in energy saving and environmental protection, and can improve safety in utilization to a certain extent.
Claims (9)
1, a kind of compound particle that contains between rare earth elemental metals strengthens metal-base composites, it is formed by strengthening body and matrix alloy, it strengthens body and accounts for 5~45% of cumulative volume, surplus is a matrix alloy, described enhancing body is the intermetallic compound particle that contains rare earth element, and described matrix alloy is the Mg alloy.
2, the compound particle that contains between rare earth elemental metals according to claim 1 strengthens metal-base composites, and it is characterized in that: described enhancing body can be YAl series intermetallic compound particle, its Al content 13.17~47.66wt%.
3, the compound particle that contains between rare earth elemental metals according to claim 1 strengthens metal-base composites, and it is characterized in that: described enhancing body can be CeAl series intermetallic compound particle, its Al content 14.35~43.51wt%.
4, the compound particle that contains between rare earth elemental metals according to claim 1 strengthens metal-base composites, and it is characterized in that: described enhancing body can be LaAl series intermetallic compound particle, its Al content 6.08~43.72wt%.
5, the compound particle that contains between rare earth elemental metals according to claim 2 strengthens metal-base composites, and it is characterized in that: described enhancing body can be YAl
2Intermetallic compound particle.
6, the compound particle that contains between rare earth elemental metals according to claim 3 strengthens metal-base composites, and it is characterized in that: described enhancing body can be CeAl
2Intermetallic compound particle.
7, the compound particle that contains between rare earth elemental metals according to claim 4 strengthens metal-base composites, and it is characterized in that: described enhancing body can be LaAl
2Intermetallic compound particle.
8, the compound particle that contains between rare earth elemental metals according to claim 1 strengthens metal-base composites, and it is characterized in that: described matrix alloy can be the Mg-Li alloy.
9, strengthen metal-base composites according to claim 1 or the 8 described compound particles that contain between rare earth elemental metals, it is characterized in that: described matrix alloy can be the Mg-Li alloy, its Li content 0~20wt%.
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Cited By (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN100387742C (en) * | 2005-11-17 | 2008-05-14 | 上海交通大学 | High damping composite Mg2Si/Mg 9A1-Y material |
| CN102753716A (en) * | 2010-02-08 | 2012-10-24 | 住友电气工业株式会社 | Magnesium alloy plate |
| CN105483481A (en) * | 2015-11-25 | 2016-04-13 | 山东银光钰源轻金属精密成型有限公司 | Method for manufacturing magnesium alloy bullet train table board supporting arm |
| CN105568096A (en) * | 2015-11-25 | 2016-05-11 | 山东银光钰源轻金属精密成型有限公司 | Magnesium alloy semi-continuous casting process |
| CN105695780A (en) * | 2016-01-28 | 2016-06-22 | 大连理工大学 | Method for preparing in-situ Al2X particle-reinforced magnesium matrix composite |
-
2003
- 2003-03-20 CN CN 03119684 patent/CN1207414C/en not_active Expired - Fee Related
Cited By (9)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN100387742C (en) * | 2005-11-17 | 2008-05-14 | 上海交通大学 | High damping composite Mg2Si/Mg 9A1-Y material |
| CN102753716A (en) * | 2010-02-08 | 2012-10-24 | 住友电气工业株式会社 | Magnesium alloy plate |
| CN102753716B (en) * | 2010-02-08 | 2014-10-29 | 住友电气工业株式会社 | Magnesium alloy plate |
| US9181608B2 (en) | 2010-02-08 | 2015-11-10 | Sumitomo Electric Industries, Ltd. | Magnesium alloy sheet |
| CN105483481A (en) * | 2015-11-25 | 2016-04-13 | 山东银光钰源轻金属精密成型有限公司 | Method for manufacturing magnesium alloy bullet train table board supporting arm |
| CN105568096A (en) * | 2015-11-25 | 2016-05-11 | 山东银光钰源轻金属精密成型有限公司 | Magnesium alloy semi-continuous casting process |
| CN105483481B (en) * | 2015-11-25 | 2017-10-27 | 山东银光钰源轻金属精密成型有限公司 | A kind of preparation method of magnesium alloy motor-car table support arm |
| CN105695780A (en) * | 2016-01-28 | 2016-06-22 | 大连理工大学 | Method for preparing in-situ Al2X particle-reinforced magnesium matrix composite |
| CN105695780B (en) * | 2016-01-28 | 2017-06-23 | 大连理工大学 | A kind of situ Al2The preparation method of X particle reinforced magnesium base compound materials |
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