CN1096544A - The infiltration analogue method for making of metal-base composites and porous metal - Google Patents
The infiltration analogue method for making of metal-base composites and porous metal Download PDFInfo
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- CN1096544A CN1096544A CN 93111553 CN93111553A CN1096544A CN 1096544 A CN1096544 A CN 1096544A CN 93111553 CN93111553 CN 93111553 CN 93111553 A CN93111553 A CN 93111553A CN 1096544 A CN1096544 A CN 1096544A
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Abstract
The infiltration analogue method for making of metal-base composites and porous metal relates to the seepage flow preparation method in the infiltration protruded packing layer that liquid metal is pressurizeed commonly used in the production.At high temperature carry out because of preparation, the percolation law and the processing parameter that influence quality product all are difficult for obtaining.The present invention is according to the fluid flow similarity principle, method with science, economy, at room temperature select suitable liquid for use, in the transparent organic glass model of filler particles is housed, simulated the liquid metal flow event, obtained percolation law and optimal processing parameter in actual production, improving production process, improve the quality of products and reduce cost, significant.
Description
The present invention relates to the seepage flow preparation method of metal-base composites and porous metal material.
Metal-base composites and porous metal material are developing novel materials, have obtained increasingly extensive using and paying attention at present in industrial production, have wide development and application prospect.For performance, quality, the yield rate that improves novel material, countries in the world particularly developed country all take much count of the seepage flow preparation research of this class material.Document one: Nobuyuki Mori, Hirofumi and Keisaku ogi:Proceedings of the Second East Asian Interna-tional Foundry Symposiym, Kitakyushu, Japan, 1991; Julyl-3:100-109; Document two: Mortensen A, MasurMC, Cornie J A and Flem-ings MC.Matau Trans A, 1989; 20A:2535-47.
The seepage flow preparation method is that METAL HEATING PROCESS is become liquid, infiltrates in the protruded packing granular layer under the impressed pressure effect, treats to obtain after the liquid metal solidification complex body-metal-base composites of metal and filler particles; This species complex is carried out aftertreatment, remove filler particles, then obtain porous metal.This preparation method, at high temperature carry out because be, in "black box", carry out in other words conj.or perhaps, so the seepage flow phenomenon of liquid metal and rule in the preparation process (for example distribution and the Changing Pattern thereof of propelling situation, seepage velocity and the pressure of liquid level) and processing parameter (for example size of the temperature of the required control of liquid metal, impressed pressure and mode thereof, seepage flow filling time etc.) all are difficult for observation and obtain.Do not understand these situations, just be difficult for correctly, reasonably designing preparation facilities, technological process and proposition processing parameter, thereby influence the quality and the yield rate of material product.With the impressed pressure is example, if impressed pressure is too small, because solidifying of liquid metal seepage flow forward position will cause filling the type failure; If excessive, can make filler particles by local compacting or fragmentation, local non-uniform areas appears in product, and the inner quality of material is descended; If excessive, even in preparation process, cause liquid metal splash from the slit of die cavity to be come out sometimes, cause security incident.At present, some processing parameters are at high temperature, determine after test of many times in preparation in kind (prototype), and this is very time-consuming, effort, expense material, expensive; And because liquid towards metal flow event has little understanding, so test has certain blindness, determined processing parameter is not necessarily best.
The objective of the invention is to overcome the weak point in the above-mentioned materials preparation process, analogy method with science, economy, acquisition is the required important seepage flow phenomenon and rule and the optimal processing parameter of knowing that influence quality product and cost in actual production, for improving production process, improve the quality of products, reduce cost, the foundation of science is provided, and guide production practice.Up to now, do not see related genera at home and abroad as yet and be similar to report of the present invention.
Influencing the factor of seepage flow preparation, mainly is liquid metal temperature and filler particles size, shape, preheating temperature, and impressed pressure size and pressuring method (upwards seepage flow or seepage flow downwards) thereof.The present invention is to the various combination situation of above-mentioned factor, according to the fluid flow similarity principle, at room temperature select liquid in the model for use, in the transparent organic glass model of filler particles is housed, simulate the liquid metal flow event in the preparation material object (prototype) of metal-base composites and porous metal, obtained in actual production, to influence important seepage flow phenomenon and the rule and the optimal processing parameter of quality product and cost.
The Sihe final condition is similar mutually for die cavity geometrical shape in die cavity in the model of the present invention and the prototype.
Filler particles in the model of the present invention, liquid select for use condition as follows:
Identical in the filler particle size of selecting for use in the model, shape, porosity, wettability and the prototype; For the particle of mm level size, the wettability in the model between liquid and the filler particles, for the wettability between liquid metal in the prototype and the preheating filler particles, its differences is very little, can ignore.
The liquid of selecting for use in the model, at room temperature its viscosity is identical with the viscosity of liquid metal in the prototype; If the temperature of liquid metal changes in the prototype, be reflected on its viscosity if change, at room temperature liquid and viscosity thereof also must change in the model, still need make the liquid in the model identical with liquid metal viscosity in the prototype.
Filler particles in the model need not preheat, and its temperature is the temperature (room temperature) of liquid in the model.Filler particles in the prototype need preheat, because between liquid metal and the filler particles heat exchange is arranged.The filler particles preheating temperature is more than critical preheating temperature, even liquid metal all gets final product more than the temperature of solidification of this metal when filling type.Because of liquid metal Seepage flow time very short (2~3 seconds), heat exchange can be ignored again, can think that under filler particles preheating situation, liquid metal temperature in flow event is constant basically, and promptly its viscosity is constant basically, the conditional likelihood of model and prototype.
Impressed pressure mode in the model of the present invention is identical with impressed pressure mode in the prototype.
Flowing in model of the present invention and the prototype, real is unsteady flow, the steady flow that all is reduced to is at short notice handled.
Under above-mentioned selected parameter and simulated condition, model experiment has shown flow phenomenon, has obtained distribution and the Changing Pattern and the optimal processing parameter of seepage velocity and pressure.According to the fluid flow similarity principle, gained result in the model can be converted to prototype, obtain seepage flow phenomenon and the rule and the optimal processing parameter of liquid metal in the prototype, instruct and be applied to production practice.Result in model experiment gained result and the prototype has good consistence.
The invention has the advantages that, overcome the weak point in the material seepage flow preparation method commonly used aborning at present, can than original method more science obtain the required important seepage flow phenomenon and rule and the optimal processing parameter of knowing that influence quality product and cost in actual production again economically, for improving production process, improve the quality of products and reduce cost, the foundation of science is provided, and guides production practice.Obviously, this has positive effect and important and practical meanings to boosting productivity and economic benefit.
Fig. 1 is a percolation model device synoptic diagram.
Fig. 2 is the impressed pressure Controlling System synoptic diagram in the model.
Fig. 3 is the instantaneous pressure measurement system schematic of the seepage flow in the model.
Fig. 4 is the relation curve of liquid level displacement (1) and time (t) in the model.
Fig. 5 is seepage flow pressure (p) and the relation curve of time (t) in the mould form.
Embodiments of the invention are as follows:
The infiltration process process that the present invention has selected to prepare with low pressure seepage flow porous metal aluminium is a simulated object.This simulation is made up of the transparent organic glass percolation model device that filler particles is housed and three parts of impressed pressure Controlling System and the instantaneous pressure measurement of seepage flow system.
Be provided with weight (1), depression bar and pressing plate (2), transmitter (3), die cavity (4), filler particles (5), inlet mouth (6), epicoele flange (7), tank cover plate (8), sink flange (9), wire netting (10), riser pipe (11), seepage flow liquid (12), tank (13), water shoot (14) in the percolation model device; Die cavity in the model and the die cavity in the prototype are right cylinder, and the final condition of die cavity import, outlet is similar; Filler particles is spherical in the model, median size d=2.5mm, filler porosity n=32.5% is all identical with prototype.The liquid of selecting for use in the model is water, and the viscosity number of liquid metal aluminium in the time of 700 ℃ is identical in viscosity at room temperature and the prototype.Filler particles need not preheat in the model, and its temperature is the temperature (room temperature) of water; The preheating temperature of filler particles is 300 ℃ in the prototype more than critical preheating temperature, when making liquid metal fill type all more than the temperature of solidification of liquid metal aluminium, can think that liquid metal aluminium temperature in flow event is constant basically, be that its viscosity is also constant basically, the conditional likelihood of model and prototype.Air pressure in the gas-holder in model and the prototype is respectively 0.1at, 0.2at, four kinds of situations of 0.3at, 0.4at, and pressuring method is identical, is upwards seepage flow.Transient Flow in mould shape and the prototype, the steady flow that all is reduced to is at short notice handled.
According to the model experiment result, according to the fluid flow similarity principle, liquid metal seepage flow phenomenon, rule and the optimal processing parameter that can obtain in the preparation (prototype) in kind are as follows.
1. in the flow event, liquid level and die cavity wall are perpendicular, and advance upward along vertical.
2. propulsive displacement of liquid level (1) and time (t) relation, available mathematical expression is represented and is calculated.Curve among Fig. 4 is respectively liquid level displacement and the time relation curve of impressed pressure under 0.1at, 0.2at, 0.3at, 0.4at situation.
3. in flow event, seepage flow pressure increases gradually, and is linear distribution along short transverse, and available mathematical expression is represented and calculated.Curve among Fig. 5 is seepage flow pressure and a time relation curve in the transmitter (1) of impressed pressure under the 0.1at situation, (2), (3), (4), (5) measured die cavity.The existence of seepage flow pressure reduction, make filler particles generation relative movement, be the one of the main reasons that causes the smooth and inhomogeneous defective of the nonmetal composition of metal-base composites of porous metal aluminium through hole, should manage not make filler particles generation relative movement in process of production as far as possible.
4. if the steady flow that unsteady flow is reduced to is at short notice handled, then represent and calculate, be non linear fluid flow through porous medium corresponding to the reynolds number Re of t sometime and resistance coefficient λ and all available mathematical expression of power loss.
5. when impressed pressure changes near the gas-holder internal gas pressure is 0.4at, not obvious for the effect of shortening filling time, consider that from economy, secure context it is that 0.4at is advisable that actual production process can be selected the gas-holder internal gas pressure.
Simulated experiment gained result and the middle gained result of preparation (prototype) in kind have good consistence.
Claims (4)
1, the infiltration analogue method for making of metal-base composites and porous metal, according to the fluid flow similarity principle, it is characterized in that, at room temperature select the liquid in the model for use, in the transparent organic glass model of filler particles is housed, simulated the liquid metal flow event in the preparation material object (prototype) of metal-base composites and porous metal.
2, the infiltration analogue method for making of metal-base composites according to claim 1 and porous metal is characterized in that, the Sihe final condition is similar mutually for the die cavity geometrical shape in the die cavity in the model and the prototype.
3, the infiltration analogue method for making of metal-base composites according to claim 1 and porous metal is characterized in that, the filler particles in the model, liquid select for use condition as follows:
A. identical in the filler particle size of selecting for use in the model, shape, porosity, wettability and the prototype; For the particle of mm level size, liquid in the model and the wettability between the filler particles can be ignored;
B. the liquid of selecting for use in the model, at room temperature its viscosity is identical with the viscosity of liquid metal in the prototype;
C. the filler particles in the model need not heat, and its temperature is the temperature (room temperature) of liquid in the model.
4, the infiltration analogue method for making of metal-base composites according to claim 1 and porous metal is characterized in that, the impressed pressure mode in the model is identical with impressed pressure mode in the prototype.
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Cited By (2)
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CN100427623C (en) * | 2006-10-20 | 2008-10-22 | 西安理工大学 | Method for preparing polymer/foam zinc-aluminium alloy composite material |
CN107695322A (en) * | 2017-09-29 | 2018-02-16 | 张勇 | A kind of device for preparing foamed aluminium and foam copper and preparation method thereof |
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CN1022768C (en) * | 1990-12-27 | 1993-11-17 | 江苏工学院 | Multi-hole metal making method |
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN100427623C (en) * | 2006-10-20 | 2008-10-22 | 西安理工大学 | Method for preparing polymer/foam zinc-aluminium alloy composite material |
CN107695322A (en) * | 2017-09-29 | 2018-02-16 | 张勇 | A kind of device for preparing foamed aluminium and foam copper and preparation method thereof |
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