CN110257655A - A kind of high diffusive distribution nano titanium diboride particle enhanced aluminum-based composite material and preparation method thereof - Google Patents

Abstract

The invention discloses a kind of high diffusives to be distributed nanometer TiB₂Particle enhanced aluminum-based composite material and preparation method thereof, first with ultrasonic wave added mixing reactant salt (K₂TiF₆/KBF₄- Al) prepare the Al-TiB of even tissue₂Intermediate alloy, wherein in-situ endogenic TiB₂Average grain diameter < 100nm of particle.With Al-TiB₂Intermediate alloy and Al are raw material, or with Al-TiB₂Intermediate alloy, Al and alloying element are raw material, by intermediate alloy dilution method by nanometer TiB₂Particle introduces in aluminium (alloy) matrix, and is aided with ultrasonic agitation processing, is then poured into mold, applies in its process of setting ultrasonic (being introduced by bottom introductory technique), to obtain high diffusive distribution nanometer TiB₂Particle enhanced aluminum-based composite material.

Description

A kind of high diffusive distribution nano titanium diboride particle enhanced aluminum-based composite material and its system Preparation Method

Technical field

The invention belongs to advanced metal-base composites preparation fields, and in particular to a kind of compound legal system of ultrasonic wave added liquid phase Standby high diffusive is distributed nanometer TiB₂The method of particulate ceramic particle enhanced aluminum-based composite material.

Background technique

Using liquid phase composite algorithm, by nano-ceramic particle introduce in aluminum melt and through solidification can prepare nano-ceramic particle/ Aluminum matrix composite.Nano-ceramic particle has refinement, invigoration effect to aluminum alloy solidification tissue, can greatly improve the ratio of alloy Intensity, specific modulus and thermal fatigue resistance have it in fields such as aerospace, automobile manufacture, electronic device, sports equipments Very wide application prospect.In addition, liquid phase composite algorithm has both, production cost is low, is suitble to the advantages that large-scale production, therefore the work Skill attracts attention in nano-ceramic particle/aluminum matrix composite preparation field.However, ceramic phase and aluminum melt wetability are poor, This prepares high quality nano ceramic particle/aluminum matrix composite totally unfavorable.On the one hand, using traditional additional particle method (being aided with mechanical stirring) is difficult for nano-ceramic particle to be fully introduced into aluminum melt；On the other hand, in conventional coagulation (gravity casting Make) in, nano-ceramic particle is acted on more segregations at α-Al crystal boundary (abbreviation crystal boundary) by solid liquid interface repulsion, causes particle in crystalline substance The extensive segregation in boundary, Yi Zengjia material hot cracking tendency and seriously reduces its plasticity and toughness, causes materials'use security risk, limits it It promotes and applies.

Summary of the invention

The purpose of the present invention is to provide a kind of high diffusive distribution nano titanium diboride particle enhanced aluminum-based composite material and Preparation method, to overcome the problems of the above-mentioned prior art, the present invention can obtain high diffusive distribution nanometer TiB₂Particle Reinforced aluminum matrix composites.

In order to achieve the above objectives, the present invention adopts the following technical scheme:

A kind of preparation method of high diffusive distribution nano titanium diboride particle enhanced aluminum-based composite material, including following step It is rapid:

Step 1: by K₂TiF₆、KBF₄Powder is mixed according to the molar ratio of 1:2, is then added in melt, and be aided with super The Al-TiB of even tissue is prepared in sound stir process₂Intermediate alloy, and obtained Al-TiB₂TiB in intermediate alloy₂? The average grain diameter of grain is less than 100nm；

Step 2: with Al-TiB obtained by Al and step 1₂Intermediate alloy is raw material, or with Al, alloying element and Al-TiB obtained by step 1₂Intermediate alloy is raw material, and by melting sources, ultrasonic agitation processing dispersion is aided in fusion process Particle is obtained containing TiB₂Particle aluminum melt；

Step 3: containing TiB for what step 2 obtained₂Particle aluminum melt is poured into mold, in melt process of setting, is passed through Bottom introductory technique introduces ultrasound, and the nanometer TiB of high diffusive distribution is obtained after solidification₂Particle enhanced aluminum-based composite material.

Further, melt temperature is 700-850 DEG C in step 1.

Further, ultrasonic agitation is handled in step 1 specifically: immerses the ultrasonic amplitude bar that material is Nb-Zr alloy In melt, sonication treatment time 5-10min, ultrasonic power 0.5-1.5kW.

Further, obtained Al-TiB₂TiB in intermediate alloy₂Mass fraction≤15% of particle.

Further, raw material is melted at 700-800 DEG C in step 2.

Further, ultrasonic agitation is handled in step 2 specifically: immerses the ultrasonic amplitude bar that material is Nb-Zr alloy In melt, sonication treatment time 5-10min, ultrasonic power 0.5-1.5kW.

Further, ultrasound is introduced by bottom introductory technique in step 3 specifically: be the ultrasound of Nb-Zr alloy by material Vibration amplitude arm is with melt contacts in mold bottom, process of setting, and ultrasonic power 0.5-1.5kW, ultrasonic time is when solidifying Between.

A kind of high diffusive distribution nano titanium diboride particle enhanced aluminum-based composite material, using above-mentioned a kind of high diffusive point The preparation method of cloth nanometer titanium diboride particle reinforced aluminum matrix composites is made.

Compared with prior art, the invention has the following beneficial technical effects:

The present invention utilizes ultrasonic wave added mixing reactant salt, the cavitation generated in aluminum melt by high-strength ultrasound, acoustic streaming effect It answers, salt-mixture reaction process can be substantially speeded up, (850 DEG C can be lower than) at a lower temperature and in the short period (being less than 10min) Synthesize the TiB that average grain diameter is less than 100nm₂Particle, and TiB₂(deposit up to 90% or more by no other impurity phases for the yield of particle ).And when using conventional hybrid reactant salt technique (no ultrasonic wave added), melt temperature need to be higher than 850 DEG C and the reaction time needs 30min or more (in order to guarantee the synthetic ratio of TiB2 particle), and obtained TiB2 particle size is sub-micron, micron grain size.It can See, TiB2 partial size can be obviously reduced using ultrasonic wave added and can effectively reduce production cost.In addition, ultrasound generates in aluminum melt Stirring action can effectively be crushed TiB₂Particle agglomeration, ultrasound cavitation effect can obviously improve TiB₂The wetting of particle and aluminum melt Property, keep it fully dispersed in melt, and be ultrasonically treated have degasification removal of impurities effect, can be obtained after casting even tissue, stomata/ It is mingled with few Al-TiB₂Intermediate alloy.The above results can realize the controllable preparation (TiB in composite material of subsequent composite material₂? Grain content is controllable), to obtain high diffusive distribution nanometer TiB₂Particle enhanced aluminum-based composite material.

Ultrasonic amplitude bar used in the present invention is Nb-Zr alloy material, is had in aluminum melt compared with conventional Ti alloy More stable (solubility of the niobium in aluminum melt is extremely low), can effectively avoid and introduce other alloying elements in aluminum melt.

Ultrasound is introduced in composite material solidification by bottom introductory technique, on the one hand, in the α-Al forming core stage, ultrasound can be with It is obviously improved TiB₂Particle is with melt wetability and ultrasonic field can make melt temperature/solute field more uniform, can be greatly improved Nucleation ability (more TiBs of the grain as heterogeneous forming core₂Particle can be carried out transgranular by α-Al forming core)；On the other hand, in α- Al grows up the stage, and ultrasonic field can accelerate the fltting speed of solid liquid interface, is conducive to TiB₂Particle is captured (more by solid liquid interface TiB₂Particle enters transgranular).In addition, the acoustic streaming effect of ultrasonic field output can avoid nanometer TiB in solidification₂Particle sinks in melt It forms sediment.Ultrasonic field can also effectively refine the solidified structure of aluminum substrate, and matrix grain refines the dispersion that can make TiB_2 nanoparticles particle Property further increases.In conclusion the present invention is remarkably improved a nanometer TiB₂Particle is in the intracorporal dispersibility of aluminium base.

Detailed description of the invention

Fig. 1 is the Al-TiB prepared in embodiment 1₂Intermediate alloy microstructure photo and object phase XRD diffracting spectrum, wherein (a) it is intermediate alloy microstructure morphology, (b) is intermediate alloy object phase XRD analysis, is (c) extraction TiB2 granule-morphology and object Phase XRD analysis (d) is TiB₂Grain diameter analysis.

Fig. 2, which is conventional coagulation (no ultrasound), and the solidification of 1 ultrasonic wave added of embodiment is lower obtains nanometer TiB₂It is particle reinforced aluminium-based The microstructure photo of composite material, wherein (a) is conventional coagulation (no ultrasound) composite material microstructure morphology, it is (b) super Sound auxiliary solidification composite material microstructure morphology.

Specific embodiment

Embodiments of the present invention are described in further detail below:

A kind of high diffusive distribution nanometer TiB₂The preparation method of particle enhanced aluminum-based composite material, the invention firstly uses super Sound auxiliary mixing reactant salt (K₂TiF₆/KBF₄- Al) prepare the Al-TiB of even tissue₂Intermediate alloy, wherein in-situ endogenic TiB₂Average grain diameter < 100nm of particle.With Al-TiB₂Intermediate alloy, Al and alloying element are raw material, or with Al-TiB₂It is intermediate Alloy and Al are raw material, by intermediate alloy dilution method by nanometer TiB₂Particle introduces in aluminium (alloy) matrix, and is aided with ultrasound Stirring, is then poured into mold, applies in its solidification ultrasonic (being introduced by bottom introductory technique), to obtain high diffusive point Cloth nanometer TiB₂Particle enhanced aluminum-based composite material.

Specifically includes the following steps:

Step 1: by K₂TiF₆、KBF₄Powder is mixed according to the molar ratio of 1:2, is then added to 700-850 DEG C of melt It is interior, and it is aided with ultrasonic agitation processing, bath surface liquid fused salt impurity is removed, the Al-TiB of even tissue is prepared after casting₂In Between alloy, wherein TiB₂The average grain diameter of particle is less than 100nm, obtained Al-TiB₂TiB in intermediate alloy₂The quality of particle Score≤15%.

Step 2: with Al-TiB obtained by Al and step 1₂Intermediate alloy is raw material, or with Al, alloying element and Al-TiB obtained by step 1₂Intermediate alloy is raw material, wherein (casting, deformation aluminium close by alloying element Si, Mg, Cu, Zn etc. Golden common alloy elements), by regulating and controlling ratio, prepare different TiB₂The aluminum matrix composite of granule content, by raw material in 700- 800 DEG C of fusings are aided with ultrasonic agitation processing discrete particles, obtain containing TiB₂Particle aluminum melt.

Step 3: TiB will be contained in step 2₂Particle aluminum melt is poured into mold, in melt process of setting, passes through bottom Introductory technique introduces ultrasound, and the nanometer TiB of high diffusive distribution is obtained after solidification₂Particle enhanced aluminum-based composite material.

The adding manner of the ultrasonic wave added stirring used in step 1 and step 2 are as follows: be the ultrasound of Nb-Zr alloy by material Vibration amplitude arm immerses in melt, sonication treatment time 5-10min, ultrasonic power 0.5-1.5kW, controls K in step 1₂TiF₆、 KBF₄The additive amount of powder can prepare different TiB₂The Al-TiB of granule content₂Intermediate alloy, ultrasonic incorporation way in step 3: will The ultrasonic amplitude bar of Nb-Zr material by mold bottom, in solidification with melt contacts, ultrasonic power 0.5-1.5kW, when ultrasonic Between be setting time.

Below with reference to embodiment, the invention will be described in further detail:

Embodiment 1

Step 1: by K₂TiF₆、KBF₄Powder carries out mixing according to molar ratio 1:2, and after being sufficiently mixed, being then added to temperature is In 800 DEG C of melt, while Nb-Zr alloy ultrasonic amplitude bar being immersed in melt, is ultrasonically treated 10min, ultrasonic power For 1.2kW, bath surface liquid fused salt impurity is removed, obtains Al-TiB after casting₂Intermediate alloy, obtained Al-TiB₂It is intermediate TiB in alloy₂The mass fraction of particle is 10%.

Step 2: with Al-TiB₂Intermediate alloy, Al are raw material, prepare 3wt.%TiB₂Particle enhanced aluminum-based composite material (TiB₂TiB in particle enhanced aluminum-based composite material₂The mass fraction of particle is 3%), to melt at 750 DEG C, is ultrasonically treated 5min, Ultrasonic power is 1.2kW.

Step 3: molten state aluminum matrix composite being poured into steel mold, while being introduced and being surpassed by bottom introductory technique Sound, ultrasonic power 1.2kW obtain nanometer TiB after solidification₂Particle enhanced aluminum-based composite material.

Fig. 1 shows the Al-10TiB using the preparation of ultrasonic wave added mixing reactant salt₂Intermediate alloy microstructure is uniform (a), And (b) is generated without other reinforced phases.In-situ endogenic TiB₂Mean particle size is less than 100nm (c)-(d).

(a) shows nanometer TiB in conventional coagulation in Fig. 2₂The main segregation of particle is in α-Al grain boundaries, and (b) display ultrasound Auxiliary solidification can effectively improve TiB₂The dispersibility of particle.

Embodiment 2

Step 1: by K₂TiF₆、KBF₄Powder carries out mixing according to molar ratio 1:2, and after being sufficiently mixed, being then added to temperature is In 750 DEG C of melt, while Nb-Zr alloy ultrasonic amplitude bar being immersed in melt, is ultrasonically treated 10min, ultrasonic power For 1.0kW, bath surface liquid fused salt impurity is removed, obtains Al-TiB after casting₂Intermediate alloy, obtained Al-TiB₂It is intermediate TiB in alloy₂The mass fraction of particle is 5%.

Step 2: with Al-TiB₂Intermediate alloy, Al are raw material, prepare 5wt.%TiB₂Particle enhanced aluminum-based composite material (TiB₂TiB in particle enhanced aluminum-based composite material₂The mass fraction of particle is 5%), to melt at 800 DEG C, is ultrasonically treated 5min.

Step 3: molten state aluminum matrix composite being poured into steel mold, while being introduced and being surpassed by bottom introductory technique Sound, ultrasonic power 1.0kW obtain nanometer TiB after solidification₂Particle enhanced aluminum-based composite material.

Embodiment 3

Step 1: by K₂TiF₆、KBF₄Powder carries out mixing according to molar ratio 1:2, and after being sufficiently mixed, being then added to temperature is In 700 DEG C of melt, while Nb-Zr alloy ultrasonic amplitude bar being immersed in melt, is ultrasonically treated 10min, ultrasonic power For 1.5kW, bath surface liquid fused salt impurity is removed, obtains Al-TiB after casting₂Intermediate alloy, obtained Al-TiB₂It is intermediate TiB in alloy₂The mass fraction of particle is 15%.

Step 2: with Al-TiB₂Intermediate alloy, Al are raw material, prepare 7wt.%TiB₂Particle enhanced aluminum-based composite material (TiB₂TiB in particle enhanced aluminum-based composite material₂The mass fraction of particle is 7%), to melt at 750 DEG C, use ultrasonic treatment 5min, ultrasonic power 1.5kW.

Step 3: molten state aluminum matrix composite being poured into steel mold, while being introduced and being surpassed by bottom introductory technique Sound, ultrasonic power 0.5kW obtain nanometer TiB after solidification₂Particle enhanced aluminum-based composite material.

Embodiment 4

Step 1: by K₂TiF₆、KBF₄Powder carries out mixing according to molar ratio 1:2, and after being sufficiently mixed, being then added to temperature is In 850 DEG C of melt, while Nb-Zr alloy ultrasonic amplitude bar being immersed in melt, is ultrasonically treated 8min, ultrasonic power is 1.0kW removes bath surface liquid fused salt impurity, obtains Al-TiB after casting₂Intermediate alloy, obtained Al-TiB₂It closes centre TiB in gold₂The mass fraction of particle is 1%.

Step 2: with Al-TiB₂Intermediate alloy, Al are raw material, prepare 10wt.%TiB₂Particle enhanced aluminum-based composite material (TiB₂TiB in particle enhanced aluminum-based composite material₂The mass fraction of particle is 10%), to melt at 700 DEG C, use ultrasonic treatment 10min, ultrasonic power 1.0kW.

Step 3: molten state aluminum matrix composite being poured into steel mold, while being introduced and being surpassed by bottom introductory technique Sound, ultrasonic power 1.0kW obtain nanometer TiB after solidification₂Particle enhanced aluminum-based composite material.

Embodiment 5

Step 1: by K₂TiF₆、KBF₄Powder carries out mixing according to molar ratio 1:2, and after being sufficiently mixed, being then added to temperature is In 850 DEG C of melt, while Nb-Zr alloy ultrasonic amplitude bar being immersed in melt, is ultrasonically treated 5min, ultrasonic power is 0.5kW removes bath surface liquid fused salt impurity, obtains Al-TiB after casting₂Intermediate alloy, obtained Al-TiB₂It closes centre TiB in gold₂The mass fraction of particle is 10%.

Step 2: with Al-TiB₂Intermediate alloy, Al, silicon addition are raw material, prepare 3wt.%TiB₂It is particle reinforced aluminium-based Composite material (TiB₂TiB in particle enhanced aluminum-based composite material₂The mass fraction of particle is 3%), to melt at 700 DEG C, using super Sonication 8min, ultrasonic power 0.5kW.

Step 3: molten state aluminum matrix composite being poured into steel mold, while being introduced and being surpassed by bottom introductory technique Sound, ultrasonic power 1.5kW obtain nanometer TiB after solidification₂Particle enhanced aluminum-based composite material.

Wherein silicon addition can also use Mg, Cu, Zn etc. (casting, wrought aluminium alloy common alloy elements).

Claims (8)

1. a kind of preparation method of high diffusive distribution nano titanium diboride particle enhanced aluminum-based composite material, which is characterized in that packet Include following steps:

Step 1: by K₂TiF₆、KBF₄Powder is mixed according to the molar ratio of 1:2, is then added in melt, and be aided with ultrasound and stir Processing is mixed, the Al-TiB of even tissue is prepared₂Intermediate alloy, and obtained Al-TiB₂TiB in intermediate alloy₂Particle Average grain diameter is less than 100nm；

Step 2: with Al-TiB obtained by Al and step 1₂Intermediate alloy is raw material, or with Al, alloying element and step 1 Obtained Al-TiB₂Intermediate alloy is raw material, and by melting sources, ultrasonic agitation processing discrete particles are aided in fusion process, It obtains containing TiB₂Particle aluminum melt；

Step 3: containing TiB for what step 2 obtained₂Particle aluminum melt is poured into mold, in melt process of setting, passes through bottom Introductory technique introduces ultrasound, and the nanometer TiB of high diffusive distribution is obtained after solidification₂Particle enhanced aluminum-based composite material.

2. a kind of preparation of high diffusive distribution nano titanium diboride particle enhanced aluminum-based composite material according to claim 1 Method, which is characterized in that melt temperature is 700-850 DEG C in step 1.

3. a kind of preparation of high diffusive distribution nano titanium diboride particle enhanced aluminum-based composite material according to claim 1 Method, which is characterized in that ultrasonic agitation is handled in step 1 specifically: immerse the ultrasonic amplitude bar that material is Nb-Zr alloy molten In vivo, sonication treatment time 5-10min, ultrasonic power 0.5-1.5kW.

4. a kind of preparation of high diffusive distribution nano titanium diboride particle enhanced aluminum-based composite material according to claim 1 Method, which is characterized in that obtained Al-TiB₂TiB in intermediate alloy₂Mass fraction≤15% of particle.

5. a kind of preparation of high diffusive distribution nano titanium diboride particle enhanced aluminum-based composite material according to claim 1 Method, which is characterized in that melt raw material at 700-800 DEG C in step 2.

6. a kind of preparation of high diffusive distribution nano titanium diboride particle enhanced aluminum-based composite material according to claim 1 Method, which is characterized in that ultrasonic agitation is handled in step 2 specifically: immerse the ultrasonic amplitude bar that material is Nb-Zr alloy molten In vivo, sonication treatment time 5-10min, ultrasonic power 0.5-1.5kW.

7. a kind of preparation of high diffusive distribution nano titanium diboride particle enhanced aluminum-based composite material according to claim 1 Method, which is characterized in that ultrasound is introduced by bottom introductory technique in step 3 specifically: the ultrasound that material is Nb-Zr alloy is shaken Width bar is with melt contacts in mold bottom, process of setting, and ultrasonic power 0.5-1.5kW, ultrasonic time is setting time.

8. a kind of high diffusive is distributed nano titanium diboride particle enhanced aluminum-based composite material, which is characterized in that use claim A kind of described in any item preparation methods of high diffusive distribution nano titanium diboride particle enhanced aluminum-based composite material of 1-7 are obtained.