CN101451223B

CN101451223B - Zirconium based amorphous alloy and manufacture method thereof

Info

Publication number: CN101451223B
Application number: CN2007101877862A
Authority: CN
Inventors: 卢昆; 姜霖琳; 张法亮; 宫清
Original assignee: BYD Co Ltd
Current assignee: BYD Co Ltd
Priority date: 2007-11-30
Filing date: 2007-11-30
Publication date: 2010-08-25
Anticipated expiration: 2027-11-30
Also published as: EP2065478B1; CN101451223A; EP2065478A1; US20090139612A1

Abstract

The invention relates to a zirconium-based amorphous alloy. The amorphous alloy contains Zr, Ti, Cu, Ni, Fe and Be, wherein the amorphous alloy also contains Sn and selectively contains ETM and LTM. The ETM can be one or several of elements of IIIB family, IVB family, VB family and VIB family in the periodic table of elements except zirconium and titanium. The LTM can be one or several of elements of IB family, IIB family, VIIB family and VIII family in the periodic table of elements except copper, nickel and iron. The adding of the tin element into the zirconium-based amorphous alloy can effectively improve the amorphous forming capacity of the material. The critical dimension of the amorphous alloy can reach a centimeter level. Simultaneously, due to good plasticity of the alloy, the alloy can avoid sudden failure when bearing load and improve the applicability of the material.

Description

A kind of zirconium-base amorphous alloy and preparation method thereof

Technical field

The present invention relates to a kind of zirconium-base amorphous alloy and preparation method thereof.

Background technology

Amorphous metal alloy, because of having special structure---the unordered short range order of long-range, and have excellent physics and a chemical property: high strength, high rigidity, wear-resisting, corrosion-resistant, bigger elastic limit and high resistance etc., in addition, also show characteristics such as good supraconductivity and low magnetic loss.Therefore, amorphous metallic material has become the most potential generally acknowledged new structural material, is widely applied to a plurality of fields such as machinery, IT electronics, military project.The appearance of large block amorphous attitude metallic substance has greatly promoted the research and the application of non-crystalline material.

But, some characteristic limitations of non-crystalline material self its application.The problem that presses for solution under the prior art condition has: 1, the production problem of large size non-crystalline material.The unordered structure of long-range to be obtained in process of production, spontaneous the moving of atom in the process of setting will be suppressed at.Rate of cooling is fast more, spontaneous move of atom and the probability of the crystalline material that formation rule is arranged is just more little.But along with the raising of product design size, its inner rate of cooling descends, and inner non-crystallization degree is low, is difficult to form the large size non-crystal structure.The size of the non-crystaline amorphous metal that prior art is produced is generally the 2-10 millimeter.2, effectively improve the problem of the plasticity index of material.Non-crystalline material is because the singularity of self structure, inside can produce various deformation mechanisms and resist deformation unlike crystalline material in carry load, so when stress reaches certain intensity unexpected fracture can take place, cause the generation of disaster accident, seriously restricted the application of amorphous material in the structured material field.Therefore, improve the plasticity of amorphous material also through becoming the focus of this area research at present.

" formation of Zr-Ti-Cu-Ni-Be-Fe block amorphous alloy and amorphous based nano composite material and performance thereof " (Zhao Deqian, Zhang Yong, Pan Mingxiang, Meng Liqin, Wang Weihua. " Acta Metallurgica Sinica " 2000.3) in a kind of Zr-Ti-Cu-Ni-Be-Fe block alloy and preparation method thereof is disclosed, this method forms nanocrystalline composite material by the Fe element that adds molecular fraction 2-10%, and its purpose is to change the susceptibility of material.Along with the increase of iron content, sharp-pointed diffraction peak occurs in the XRD figure, and significantly crystallization phenomenon is promptly arranged, and the iron that the interpolation high level be described influences to some extent to the amorphous formation ability of alloy.This achievement in research can not solve the size and the plasticity problem of non-crystaline amorphous metal.

Summary of the invention

The objective of the invention is provides a kind of centimetre-sized zirconium-base amorphous alloy with good plasticity in order to overcome the little and shortcoming that plasticity is relatively poor of the ubiquitous volume of present amorphous alloy material.

Another object of the present invention provides a kind of preparation method of above-mentioned alloy.

The invention provides a kind of zirconium-base amorphous alloy, this alloy contains Zr, Ti, Cu, Ni, Fe and Be, wherein, this alloy also contains Sn, and optionally contain ETM and LTM, described ETM is one or more in the element except that zirconium and titanium in periodic table of elements IIIB family, IVB family, VB family, the group vib, and described LTM is one or more in the element outside periodic table of elements IB family, IIB family, VIIB family and VIII family copper removal, nickel and the iron.

The present invention also provides the preparation method of above-mentioned alloy; this method is included under the protection of inert gas; the non-crystaline amorphous metal raw material is carried out vacuum melting and cooling forming; wherein; the raw material of described non-crystaline amorphous metal comprises: Zr; Ti; Cu; Ni; Fe; and Be; wherein; the raw material of described non-crystaline amorphous metal also comprises ETM and the LTM that Sn and selectivity contain; described ETM is a periodic table of elements IIIB family; IVB family; VB family; in the element in the group vib except that zirconium and titanium one or both, described LTM are periodic table of elements IB family; IIB family; copper removal in VIIB family and the VIII family; in the element outside nickel and the iron one or both.

Add tin element in the zirconium-base amorphous alloy provided by the invention, can effectively improve the amorphous formation ability of material, the critical size of alloy of the present invention can reach centimetre-sized.Simultaneously, have good plasticity, avoided sudden failure when carry load, improved the applicability of material.

Description of drawings

The accurate ternary phase diagrams of Fig. 1 non-crystaline amorphous metal of the present invention (Zr, Ti, Sn)-(Cu, Ni)-(Be, Fe);

The stress-strain diagram of the non-crystaline amorphous metal that Fig. 2 makes for embodiment 1 and Comparative Examples 1;

The XRD figure of the non-crystaline amorphous metal that Fig. 3 makes for embodiment 1-5 and Comparative Examples 1.

Embodiment

Zirconium-base amorphous alloy provided by the invention has the represented composition of following general formula: (Zr _xTi _ySn _z) _aETM _b(Cu _mNi _n) _cFe _dLTM _eBe _f, wherein, a, b, c, d, e and f are molecular fraction, a+b+c+d+e+f=100, and 30≤a≤75,0≤b≤15,10≤c≤35,0.1≤d≤15,0≤e≤15,0.1≤f≤35; X, y and z are atomic ratio, x+y+z=1, and 0.6≤x≤0.85,0.01x≤z≤0.1x; M and n are atomic ratio, m+n=1, and 0.5≤m≤0.65.

Under the preferable case, 40≤a≤60,0≤b≤10,15≤c≤25,0.5≤d≤5,0≤e≤10,15≤f≤25.

Wherein, ETM is one or more in other elements except that zirconium and titanium in periodic table of elements IIIB family, IVB family, VB family, the group vib, is preferably in scandium, yttrium, lanthanum, cerium, praseodymium, neodymium, hafnium, vanadium, niobium, tantalum, chromium, molybdenum and the tungsten one or both.LTM is one or more in other element outside copper removal, nickel and the iron in periodic table of elements IB family, IIB family, VIIB family and the VIII family, is preferably in manganese, technetium, rhenium, ruthenium, osmium, cobalt, rhodium, iridium, palladium, platinum, silver, gold, zinc, cadmium and the mercury one or both.The summation of element kind is preferably the 1-3 kind among ETM and the LTM.

The accurate ternary phase diagrams of the composition of alloy of the present invention as shown in Figure 1.The determined amorphous of composition variation range of the big parallelogram Regional Representative non-crystaline amorphous metal provided by the invention among the figure forms the zone, and the amorphous that the composition variation range of little parallelogram Regional Representative preferable case is determined forms the zone.The element in the non-crystaline amorphous metal has been represented on leg-of-mutton three summits of outermost respectively, the situation of the alloy described in the figure when not comprising ETM and LTM.The numeral that marks on each among the figure is to represent atoms of elements percentage ratio in the alloy.

The preparation method of zirconium-base amorphous alloy provided by the invention, this method is included under the protection of inert gas, and the non-crystaline amorphous metal raw material is carried out vacuum melting and cooling forming.

The preparation raw material of zirconium-base amorphous alloy provided by the present invention comprises Zr, Ti, Cu, Ni, Fe and Be, and wherein, its preparation raw material also comprises ETM and the LTM that Sn and selectivity contain.

The add-on of various elements will make that the alloy composition of making is the represented composition of following general formula: (Zr _xTi _ySn _z) _aETM _b(Cu _mNi _n) _cFe _dLTM _eBe _f, wherein, a, b, c, d, e and f are molecular fraction, a+b+c+d+e+f=100, and 30≤a≤75,0≤b≤15,10≤c≤35,0.1≤d≤15,0≤e≤15,0.1≤f≤35; X, y and z are atomic ratio, x+y+z=1, and 0.6≤x≤0.85,0.01x≤z≤0.1x; M and n are atomic ratio, m+n=1, and 0.5≤m≤0.65.Under the preferable case, 40≤a≤60,0≤b≤10,15≤c≤25,0.5≤d≤5,0≤e≤10,15≤f≤25.

ETM is one or more in other elements except that zirconium and titanium in periodic table of elements IIIB family, IVB family, VB family, the group vib, is preferably in scandium, yttrium, lanthanum, cerium, praseodymium, neodymium, hafnium, vanadium, niobium, tantalum, chromium, molybdenum and the tungsten one or both.LTM is one or more in other element outside copper removal, nickel and the iron in periodic table of elements IB family, IIB family, VIIB family and the VIII family, is preferably in manganese, technetium, rhenium, ruthenium, osmium, cobalt, rhodium, iridium, palladium, platinum, silver, gold, zinc, cadmium and the mercury one or both.The summation of element kind is preferably the 1-3 kind among ETM and the LTM.

The method of melting of the present invention is the melting method of various routines in this area, as long as with the abundant fusion of non-crystaline amorphous metal raw material, for example, can earlier the non-crystaline amorphous metal raw material be mixed under molten state and is cooled to ingot, then with described ingot remelting.Can be with various alloying element fusions in arc-melting furnace or induction melting furnace, the fused temperature and time is along with the difference of selected heating process has some variations, general melt temperature can be 1000-2700 ℃, be preferably 1500-2000 ℃, fusion time is 5-20 minute, vacuum tightness is not more than 200Pa, is preferably 0.01-5Pa.Reflow process generally adopts arc melting, induction melting or resistance melting, and remelting temperature can be 1000-2300 ℃, is preferably 1000-1500 ℃.Vacuum tightness is not more than 200Pa, is preferably 0.01-5Pa.Described forming method can be the forming method of various routines in this area, for example gets rid of band, copper mold casting, inhales casting, die casting, jet moulding or water quenching, and the speed of cooling of described cooling forming is 10-10 ⁴K/s.Because the critical size difference of different moietys can be selected different mode moulding for use.Described rare gas element is selected from neutral element gas and SF in the periodic table of elements ₆In one or more.

Below by embodiment the present invention is described in more detail.

Embodiment 1

Present embodiment is used to illustrate the preparation of zirconium-base amorphous alloy provided by the invention.

With raw material Zr, Ti, Sn, Cu, Ni, Fe, Be altogether 25g according to following ratio: (Zr _0.74Ti _0.25Sn _0.01) _55.34(Cu _0.56Ni _0.44) _20.65Fe _1.96Be _22.05, being positioned in the arc-melting furnace (Shenyang scientific instrument Manufacturing Co., Ltd) and being evacuated to 5Pa, 2000 ℃ of meltings are 6 minutes under the condition of argon shield, are cooled to ingot after fully stirring.With this ingot with 1500 ℃ of fusings of electric-arc heating mode after, with copper mold casting cooling rate 10 ²K/s makes zirconium-base amorphous alloy sample C1.

Embodiment 2

Present embodiment is used to illustrate the preparation method of zirconium-base amorphous alloy provided by the invention.

Described according to inventive method, raw material Zr, Ti, Sn, Cu, Ni, Fe, Be are total to 200kg according to (Zr _0.74Ti _0.25Sn _0.01) _55.34(Cu _0.56Ni _0.44) _20.65Fe _1.96Be _22.05Ratio be positioned in the induction melting furnace (middle north science and technology) and be evacuated to 5Pa, 1800 ℃ of meltings are 10 minutes under the condition of argon shield, are cooled to ingot after fully stirring.After the 1200 ℃ of fusings of mode of this ingot, with the method cooling rate 10 of die casting with resistive heating ⁴K/s makes zirconium-base amorphous alloy sample C2.

Embodiment 3

With raw material Zr, Ti, Sn, Y, Nb, Cu, Ni, Fe, Be altogether 20g according to following ratio: (Zr _0.80Ti _0.17Sn _0.03) ₄₀Y ₅Nb ₅(Cu _0.64Ni _0.36) ₂₅Fe ₅Be ₂₀, be positioned over and be evacuated to 200Pa in the silica tube, under the condition of argon shield with the mode melting of 2000 ℃ of induction heating 5 minutes), be cooled to ingot after fully stirring.After the 1500 ℃ of fusings of mode of this ingot, with water quenching cooling rate 10 with induction heating ³K/s makes zirconium-base amorphous alloy sample C3.

Embodiment 4

With raw material Zr, Ti, Sn, Cu, Ni, Co, Fe, Be altogether 200kg according to following ratio: (Zr _0.65Ti _0.29Sn _0.06) ₅₀(Cu _0.5Ni _0.5) ₂₀Co ₁₀Fe ₃Be ₁₇, be positioned over and be evacuated to 5Pa in the induction melting furnace, under the condition of argon shield, carried out melting 10 minutes in the mode of 1800 ℃ of induction heating, be cooled to ingot after fully stirring.After the 1000 ℃ of fusings of mode of this ingot, to get rid of band method cooling rate 10 with resistive heating ⁴K/s makes zirconium-base amorphous alloy sample C4.

Embodiment 5

With raw material Zr, Ti, Sn, W, Cu, Ni, Pd, Zn, Fe, Be altogether 20g according to following ratio: (Zr _0.75Ti _0.24Sn _0.01) ₆₀W ₃(Cu _0.55Ni _0.45) ₁₅Pd ₂Zn ₁Fe ₄Be ₁₅, be positioned over and be evacuated to 2 * 10 in the silica tube ^-2Pa with the mode melting of 2000 ℃ of induction heating 5 minutes, is cooled to ingot after fully stirring under the condition of argon shield.After the 1500 ℃ of fusings of mode of this ingot, with water quenching cooling rate 10 with induction heating ⁴K/s makes zirconium-base amorphous alloy sample C5.

Comparative Examples 1

This Comparative Examples is used to the non-crystalline material that illustrates that prior art makes.

Raw material Zr, Ti, Cu, Ni, Be, Fe are total to 25g according to Zr ₄₁Ti ₁₄Cu ₁₁Ni _9.5Fe ₂Be _22.5Ratio is positioned in the arc-melting furnace (Shenyang scientific instrument Manufacturing Co., Ltd) and is evacuated to 5Pa, and 2000 ℃ of meltings are 6 minutes under the condition of argon shield, is cooled to ingot after fully stirring.With this ingot with 1500 ℃ of fusings of electric-arc heating mode after, with copper mold casting cooling rate 10 ²K/s makes zirconium-base amorphous alloy sample D1.

Testing method

(1) compression experiment

Be to carry out on 3 tons the CMT5000 serial experiment machine at the tonnage of newly thinking carefully company, loading velocity 0.5 mm/min, the stress-strain situation of specimen C1 and D1, test result is as shown in Figure 2.

(2) hardness test

Hardness is tested on Micro Hardness Text Hv1000 Vickers' hardness test machine, and pressure head weight is 200 grams, and the loading time is 10 seconds, and every kind of sample is got three numerical value, gets its arithmetical av at last, and the result is as shown in table 1.

(3) XRD analysis

Whether the XRD powder diffraction analysis is that material is carried out material phase analysis, be amorphous to judge alloy, and this experiment is to carry out on model is the x-ray powder diffraction instrument of D-MAX2200PC.With the copper target emanation, its incident wavelength λ=1.54060 dusts, acceleration voltage are 40 kilovolts, and electric current is 20 milliamperes, adopt step-scan, and scanning step is 0.04 degree, and test result as shown in Figure 3.

(4) critical size test

The sample of the wedge shape that forms in the copper mold thickness with 1 millimeter from the angle of wedge shape is cut, then aforesaid XRD analysis is carried out in the cross section of cutting back formation, measure structure type, if structure type is a non-crystaline amorphous metal, then continue cutting, till structure type was not non-crystaline amorphous metal, record cutting total thickness, described critical size were this total thickness and deduct thickness after 1 millimeter.The result is as shown in table 1.

Table 1

Numbering	C1	C2	C3	C4	C5	D1
Numbering	C1	C2	C3	C4	C5	D1	Critical size/mm	＞14	＞14	14	12	12	8
Average hardness/Hv	553	553	547	539	548	537	Critical size/mm	＞14	＞14	14	12	12	8

From the test result of table 1 as can be seen, the critical size of the zirconium-base amorphous alloy that the present invention makes surpasses 1 centimetre, has higher hardness simultaneously.As can be seen from Figure 3, all do not have sharp-pointed diffraction peak to occur in the XRD figure of sample C1, C2, C3, C4, C5 and D1, illustrate that the non-crystallization degree of these alloys is very high.As can be seen from Figure 2, the zirconium-base amorphous alloy D1 that zirconium-base amorphous alloy C1 that the present invention makes and prior art make is when bearing the stress of same intensity, curve overlaps substantially in the stress lower region, but along with stress intensity increases, D1 can only produce very little strain, very fast fracture, and represent the curve of C1 to bend, illustrate that its adaptability to changes obviously is better than D1, i.e. the zirconium-base amorphous alloy that the present invention makes has stronger plasticity.

Claims

1. a zirconium-base amorphous alloy is characterized in that, this non-crystaline amorphous metal has the composition shown in the following general formula: (Zr _xTi _ySn _z) _aETM _b(Cu _mNi _n) _cFe _dLTM _eBe _fWherein, described ETM is one or more in the element except that zirconium and titanium in periodic table of elements IIIB family, IVB family, VB family, the group vib, and described LTM is one or more in the element outside copper removal, nickel and the iron in periodic table of elements IB family, IIB family, VIIB family and the VIII family; A, b, c, d, e and f are molecular fraction, a+b+c+d+e+f=100, and 30≤a≤75,0≤b≤15,10≤c≤35,0.1≤d≤15,0≤e≤15,0.1≤f≤35; X, y and z are atomic ratio, x+y+z=1, and 0.6≤x≤0.85,0.01x≤z≤0.1x; M and n are atomic ratio, m+n=1, and 0.5≤m≤0.65.

2. non-crystaline amorphous metal according to claim 1, wherein, 40≤a≤60,0≤b≤10,15≤c≤25,0.5≤d≤5,0≤e≤10,15≤f≤25.

3. non-crystaline amorphous metal according to claim 1, wherein, described ETM is one or both in scandium, yttrium, lanthanum, cerium, praseodymium, neodymium, hafnium, vanadium, niobium, tantalum, chromium, molybdenum and the tungsten, described LTM is one or both in manganese, technetium, rhenium, ruthenium, osmium, cobalt, rhodium, iridium, palladium, platinum, silver, gold, zinc, cadmium and the mercury, and the summation of element kind is the 1-3 kind among ETM and the LTM.

4. the preparation method of a non-crystaline amorphous metal, this method is included under the protection of inert gas, and the non-crystaline amorphous metal raw material is carried out vacuum melting and cooling forming, and the adding of the raw material of described non-crystaline amorphous metal makes non-crystaline amorphous metal have the composition shown in the following general formula: (Zr _xTi _ySn _z) _aETM _b(Cu _mNi _n) _cFe _dLTM _eBe _fWherein, described ETM is one or more in the element except that zirconium and titanium in periodic table of elements IIIB family, IVB family, VB family, the group vib, and described LTM is one or more in the element outside periodic table of elements IB family, IIB family, VIIB family and VIII family copper removal, nickel and the iron; A, b, c, d, e and f are molecular fraction, a+b+c+d+e+f=100, and 30≤a≤75,0≤b≤15,10≤c≤35,0.1≤d≤15,0≤e≤15,0.1≤f≤35; X, y and z are atomic ratio, x+y+z=1, and 0.6≤x≤0.85,0.01x≤z≤0.1x; M and n are atomic ratio, m+n=1, and 0.5≤m≤0.65.

5. method according to claim 4, wherein, 40≤a≤60,0≤b≤10,15≤c≤25,0.5≤d≤5,0≤e≤10,15≤f≤25.

6. method according to claim 4, wherein, described ETM is one or both in scandium, yttrium, lanthanum, cerium, praseodymium, neodymium, hafnium, vanadium, niobium, tantalum, chromium, molybdenum and the tungsten, described LTM is one or both in manganese, technetium, rhenium, ruthenium, osmium, cobalt, rhodium, iridium, palladium, platinum, silver, gold, zinc, cadmium and the mercury, and the summation of element kind is the 1-3 kind among ETM and the LTM.

7. method according to claim 4, wherein, the method for described vacuum melting comprises mixes the non-crystaline amorphous metal raw material earlier and is cooled to ingot under molten state, then with described ingot remelting.

8. method according to claim 4, wherein, the condition of described vacuum melting comprises that smelting temperature is 1000-2700 ℃, and smelting time is 0.5-5 minute, and vacuum tightness is the 0.01-5 handkerchief.

9. method according to claim 4, wherein, the speed of cooling of described cooling forming is 10-10 ⁴K/s.

10. method according to claim 4, wherein, described rare gas element is selected from neutral element gas and SF in the periodic table of elements ₆In one or more.