EP2326738B9 - Milling cone for a compression crusher - Google Patents

Milling cone for a compression crusher Download PDF

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Publication number
EP2326738B9
EP2326738B9 EP09782200.1A EP09782200A EP2326738B9 EP 2326738 B9 EP2326738 B9 EP 2326738B9 EP 09782200 A EP09782200 A EP 09782200A EP 2326738 B9 EP2326738 B9 EP 2326738B9
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EP
European Patent Office
Prior art keywords
titanium carbide
micrometric
milling cone
granules
globular particles
Prior art date
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EP09782200.1A
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German (de)
French (fr)
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EP2326738A1 (en
EP2326738B1 (en
Inventor
Guy Berton
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Magotteaux International SA
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Magotteaux International SA
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B02CRUSHING, PULVERISING, OR DISINTEGRATING; PREPARATORY TREATMENT OF GRAIN FOR MILLING
    • B02CCRUSHING, PULVERISING, OR DISINTEGRATING IN GENERAL; MILLING GRAIN
    • B02C2/00Crushing or disintegrating by gyratory or cone crushers
    • B02C2/005Lining
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22DCASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
    • B22D19/00Casting in, on, or around objects which form part of the product
    • B22D19/06Casting in, on, or around objects which form part of the product for manufacturing or repairing tools
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22DCASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
    • B22D19/00Casting in, on, or around objects which form part of the product
    • B22D19/14Casting in, on, or around objects which form part of the product the objects being filamentary or particulate in form
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22FWORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
    • B22F3/00Manufacture of workpieces or articles from metallic powder characterised by the manner of compacting or sintering; Apparatus specially adapted therefor ; Presses and furnaces
    • B22F3/10Sintering only
    • B22F3/1039Sintering only by reaction
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C1/00Making non-ferrous alloys
    • C22C1/04Making non-ferrous alloys by powder metallurgy
    • C22C1/05Mixtures of metal powder with non-metallic powder
    • C22C1/051Making hard metals based on borides, carbides, nitrides, oxides or silicides; Preparation of the powder mixture used as the starting material therefor
    • C22C1/053Making hard metals based on borides, carbides, nitrides, oxides or silicides; Preparation of the powder mixture used as the starting material therefor with in situ formation of hard compounds
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C1/00Making non-ferrous alloys
    • C22C1/04Making non-ferrous alloys by powder metallurgy
    • C22C1/05Mixtures of metal powder with non-metallic powder
    • C22C1/058Mixtures of metal powder with non-metallic powder by reaction sintering (i.e. gasless reaction starting from a mixture of solid metal compounds)
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C1/00Making non-ferrous alloys
    • C22C1/10Alloys containing non-metals
    • C22C1/1036Alloys containing non-metals starting from a melt
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C1/00Making non-ferrous alloys
    • C22C1/10Alloys containing non-metals
    • C22C1/1036Alloys containing non-metals starting from a melt
    • C22C1/1068Making hard metals based on borides, carbides, nitrides, oxides or silicides
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C33/00Making ferrous alloys
    • C22C33/02Making ferrous alloys by powder metallurgy
    • C22C33/0207Using a mixture of prealloyed powders or a master alloy
    • C22C33/0228Using a mixture of prealloyed powders or a master alloy comprising other non-metallic compounds or more than 5% of graphite
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C33/00Making ferrous alloys
    • C22C33/02Making ferrous alloys by powder metallurgy
    • C22C33/0257Making ferrous alloys by powder metallurgy characterised by the range of the alloying elements
    • C22C33/0278Making ferrous alloys by powder metallurgy characterised by the range of the alloying elements with at least one alloying element having a minimum content above 5%
    • C22C33/0292Making ferrous alloys by powder metallurgy characterised by the range of the alloying elements with at least one alloying element having a minimum content above 5% with more than 5% preformed carbides, nitrides or borides
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C38/00Ferrous alloys, e.g. steel alloys
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B02CRUSHING, PULVERISING, OR DISINTEGRATING; PREPARATORY TREATMENT OF GRAIN FOR MILLING
    • B02CCRUSHING, PULVERISING, OR DISINTEGRATING IN GENERAL; MILLING GRAIN
    • B02C2210/00Codes relating to different types of disintegrating devices
    • B02C2210/02Features for generally used wear parts on beaters, knives, rollers, anvils, linings and the like
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22FWORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
    • B22F5/00Manufacture of workpieces or articles from metallic powder characterised by the special shape of the product
    • B22F2005/002Tools other than cutting tools
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22FWORKING METALLIC POWDER; MANUFACTURE OF ARTICLES FROM METALLIC POWDER; MAKING METALLIC POWDER; APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER
    • B22F5/00Manufacture of workpieces or articles from metallic powder characterised by the special shape of the product
    • B22F2005/005Article surface comprising protrusions
    • CCHEMISTRY; METALLURGY
    • C22METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
    • C22CALLOYS
    • C22C2204/00End product comprising different layers, coatings or parts of cermet

Definitions

  • the present invention relates to a composite grinding cone for compression crushers in the field of rock crushing in extractive industries such as mines, quarries, cement plants, etc., but also in the recycling industry, etc., as well as than a method of manufacturing such cones.
  • compression crusher cone crushers or gyratory crushers equipped with grinding cones constituting the main wear part of these machines.
  • Cone crushers or gyratory crushers have a cone-shaped wear part called the grinding cone. This type of cone is the subject of this patent application.
  • the cone has the function of being in direct contact with the rock or the material to be ground during the process phase, where very high compressive stresses are applied to the material to be crushed.
  • Compression crushers are used in the early stages of the production line to drastically reduce the size of the rock, in the extractive industries (mines, quarries, cement plants, ...) and recycling.
  • the document JP 53 17731 proposes a solution that consists of alternating zones that are more resistant and less resistant to wear, in the direction of the generator of a grinding cone. This technique has the effect of generating on the surface of the cone a relief that would be favorable to the extension of the service life of the part.
  • the present invention discloses a composite grinding cone for compression crushers having improved wear resistance while maintaining good impact resistance. This property is obtained by a composite reinforcement structure specifically designed for this application, a material that alternates on a millimeter scale dense zones in fine micrometric globular particles of metal carbides with zones that are practically free of them within the metallic matrix. grinding cone.
  • the present invention also provides a method for obtaining said reinforcing structure.
  • the present invention discloses a composite grinding cone for compression crushers, said grinding cone comprising a ferrous alloy reinforced at least in part with titanium carbide according to a defined geometry, wherein said reinforced portion comprises an alternating macro-microstructure of zones millimeters concentrated in micrometric globular particles of titanium carbide separated by millimetric zones essentially free of micrometric globular particles of titanium carbide, said zones concentrated in micrometric globular particles of titanium carbide forming a microstructure in which the micrometric interstices between said globular particles are also occupied by said ferrous alloy.
  • the present invention also discloses a composite grinding cone obtained by the method of any one of claims 11 to 13.
  • FIGS 1 and 2 show an overall three-dimensional view of the different types of machines in which grinding cones according to the present invention are used.
  • the figure 3 shows a three-dimensional view of a grinding cone and how the reinforcement (s) can be arranged to achieve the desired purpose. (reinforcement geometry)
  • the figure 5 represents a binocular view of a polished, unengaged surface of a section of the reinforced portion of a cone according to the invention with millimetric zones (in light gray) concentrated micrometric globular titanium carbide (TiC nodules) ).
  • the dark part represents the metal matrix (steel or cast iron) filling at the same time the space between these concentrated zones in micrometric globular titanium carbide but also the spaces between the globules themselves.
  • the figures 6 and 7 represent SEM electron microscopic views of micrometric globular titanium carbide on polished and untouched surfaces at different magnifications. We see that in this particular case most of the globules of titanium carbide have a size less than 10 microns.
  • the figure 8 represents a view of micrometric globular titanium carbide on a fracture surface taken by SEM electron microscope. It can be seen that the globules of titanium carbide are perfectly incorporated in the metal matrix. This proves that the casting metal completely infiltrates (impregnates) the pores during casting once the chemical reaction between titanium and carbon is initiated.
  • the SHS or " s elf-propagating h igh temperature s ynthesis" reaction is a self-propagating, high-temperature synthesis reaction in which reaction temperatures are generally greater than 1500 ° C or even 2000. ° C.
  • reaction temperatures are generally greater than 1500 ° C or even 2000. ° C.
  • the reaction between titanium powder and carbon powder to obtain titanium carbide TiC is highly exothermic. Only a little energy is needed to initiate the reaction locally. Then, the reaction will spontaneously propagate to the entire mixture of reagents thanks to the high temperatures reached. After initiation of the reaction, there is a reaction front which propagates spontaneously (self-propagated) and which makes it possible to obtain titanium carbide from titanium and carbon.
  • the titanium carbide thus obtained is said to be "obtained in situ because it does not come from the cast ferrous alloy.
  • the reactant powder mixtures comprise carbon powder and titanium powder and are compressed into plates and then crushed to obtain granules ranging in size from 1 to 12 mm, preferably from 1 to 6 mm, and particularly preferably from 1.4 to 4 mm. These granules are not 100% compacted. They are generally compressed between 55 and 95% of the theoretical density. These granules allow easy use / handling (see Fig. 3a-3h).
  • millimetric granules of mixed carbon and titanium powders obtained according to the diagrams of FIG. 4a-4h constitute the precursors of the titanium carbide to be created and make it possible to easily fill mold parts of various or irregular shapes.
  • These granules can be held in place in the mold 15 by means of a dam 16, for example.
  • the shaping or assembly of these granules can also be done using an adhesive.
  • the composite grinding cone according to the present invention has a reinforcing macro-microstructure which may alternatively be called an alternating structure of concentrated micrometric globular particles of titanium carbide separated by zones which are substantially free of it.
  • a reinforcing macro-microstructure which may alternatively be called an alternating structure of concentrated micrometric globular particles of titanium carbide separated by zones which are substantially free of it.
  • Such a structure is obtained by the reaction in the mold of the granules comprising a mixture of powders of carbon and titanium. This reaction is initiated by the heat of casting of the cast iron or steel used to pour the whole piece and thus both the unreinforced part and the reinforced part (see Fig. 3e).
  • the casting therefore triggers an exothermic synthesis reaction self-propagated at high temperature of the mixture of powders of carbon and titanium compacted in the form of granules (self-propagating high-temperature synthesis - SHS) and previously placed in the mold 15.
  • the reaction then has the distinction of continuing to spread as soon as it is initiated.
  • This high temperature synthesis allows easy infiltration of all millimetric and micrometric interstices by cast iron or casting steel ( Fig. 4g & 4h ). By increasing the wettability, the infiltration can be done on any thickness or depth of reinforcement of the grinding cone. It advantageously makes it possible, after SHS reaction and infiltration by an external casting metal, to create one or more reinforcement zones on the grinding cone comprising a high concentration of micrometric globular particles of titanium carbide (which could also be called clusters of nodules), which areas have a size of the order of a millimeter or a few millimeters, and which alternate with areas substantially free of globular titanium carbide.
  • the zones of reinforcement where these granules were found show a concentrated dispersion of micrometric globular particles 4 of TiC carbide (globules) whose micrometric interstices 3 have also been infiltrated by the casting metal. which is here cast iron or steel. It is important to note that the millimetric and micrometric interstices are infiltrated by the same metal matrix as that which constitutes the unreinforced part of the grinding cone; this allows a total freedom of choice of the casting metal.
  • the reinforcement zones with a high concentration of titanium carbide are composed of globular micrometric particles of TiC in significant percentage (between about 35 and about 70% by volume) and the ferrous alloy infiltration.
  • Micrometric globular particles are understood to mean globally spheroidal particles having a size ranging from a few ⁇ m to a few tens of ⁇ m at the most, the vast majority of these particles having a size of less than 50 ⁇ m, and even 20 ⁇ m, or even less than 10 ⁇ m.
  • TiC globules This globular form is characteristic of a method for obtaining titanium carbide by self-propagating synthesis SHS (see Fig. 7 ).
  • the process for obtaining the granules is illustrated in FIG. 4a-4h.
  • the granules of carbon / titanium reagents are obtained by compaction between rollers 10 in order to obtain strips that are then crushed in a crusher 11.
  • the mixture of the powders is made in a mixer 8 consisting of a tank equipped with blades , to promote homogeneity.
  • the mixture then passes into a granulation apparatus through a hopper 9.
  • This machine comprises two rollers 10, through which the material is passed. Pressure is applied to these rollers 10, which compresses the material. A strip of compressed material is obtained at the outlet, which is then crushed in order to obtain the granules.
  • These granules are then sieved to the desired particle size in a sieve 13.
  • the degree of compaction of the bands depends on the applied pressure (in Pa) on the rollers (diameter 200 mm, width 30 mm). For a low level of compaction, of the order of 10 6 Pa, we obtain a density on the bands of the order of 55% of the theoretical density. After passing through the rollers 10 to compress this material, the apparent density of the granules is 3.75 x 0.55, ie 2.06 g / cm 3 .
  • the granules obtained from the raw material Ti + C are porous. This porosity varies from 5% for highly compressed granules, to 45% for slightly compressed granules.
  • the granules obtained generally have a size between 1 and 12 mm, preferably between 1 and 6 mm, and particularly preferably between 1.4 and 4 mm.
  • the granules are made as described above. To obtain a three-dimensional structure superstructure / macro-microstructure with these granules, they are available in the areas of the mold where it is desired to reinforce the part. This is achieved by agglomerating the granules either by means of an adhesive, or by confining them in a container, or by any other means (dam 16).
  • the bulk density of the stack of Ti + C granules is measured according to ISO 697 and depends on the level of compaction of the bands, the granulometric distribution of the granules and the crushing mode of the bands, which influences the shape of the granules .
  • the bulk density of these Ti + C granules is generally of the order of 0.9 g / cm 3 to 2.5 g / cm 3 depending on the level of compaction of these granules and the density of the stack.
  • the compactness of the granules was obtained by varying the pressure between the rolls by 10 to 250 ⁇ 10 5 Pa. Reinforcement has been done by placing granules in a metal container, which is then conveniently placed in the mold where the grinding cone is likely to be reinforced. Then we cast the steel or cast in this mold.
  • a grinding cone whose reinforced areas comprise an overall volume percentage of TiC of about 42%.
  • a band is produced by compaction at 85% of the theoretical density of a mixture of C and Ti. After crushing, the granules are sieved to obtain a pellet size of between 1.4 and 4 mm. A bulk density of the order of 2.1 g / cm 3 (35% of space between the granules + 15% of porosity in the granules) is obtained.
  • the granules are placed in the mold at the location of the part to be reinforced, which thus comprises 65% by volume of porous granules.
  • a chromium cast iron (3% C, 25% Cr) was then cast at about 1500 ° C in a non-preheated sand mold.
  • the reaction between Ti and C is initiated by the heat of melting. This casting is done without a protective atmosphere.
  • 65% by volume of zones with a high concentration of approximately 65% of globular titanium carbide are obtained in the reinforced part, ie 42% by global volume of TiC in the reinforced part of the grinding cone.
  • a grinding cone whose reinforced areas comprise a global volume percentage of TiC of about 30%.
  • a 70% compaction band is made of the theoretical density of a mixture of C and Ti.
  • the granules are sieved to obtain a pellet size of between 1.4 and 4 mm.
  • a bulk density of the order of 1.4 g / cm 3 (45% of space between the granules + 30% of porosity in the granules) is obtained.
  • the granules are placed in the part to be reinforced, which thus comprises 55% by volume of porous granules.
  • 55% by volume of zones with a high concentration of approximately 53% of globular titanium carbide, ie approximately 30% by volume of TiC in the reinforced portion of the grinding cone, are obtained.
  • a grinding cone whose reinforced areas comprise a global volume percentage of TiC of about 20%.
  • a 60% compaction band is made of the theoretical density of a mixture of C and Ti.
  • the granules are sieved so as to obtain a granule size of between 1 and 6 mm.
  • a bulk density of the order of 1.0 g / cm 3 (55% of space between the granules + 40% of porosity in the granules) is obtained.
  • the granules are placed in the part to be reinforced, which thus comprises 45% by volume of porous granules.
  • 45% by volume of zones concentrated to about 45% of globular titanium carbide are obtained, ie 20% by global volume of TiC in the reinforced part of the grinding cone.
  • Example 2 it was sought to attenuate the intensity of the reaction between carbon and titanium by adding a ferrous alloy powder.
  • a grinding cone whose reinforced zones comprise a global volume percentage of TiC of about 30%.
  • a compaction band is produced at 85% of the theoretical density of a mixture by weight of 15% of C, 63% of Ti and 22% of Fe.
  • the granules are sieved to obtain a granule size between 1.4 and 4 mm.
  • a bulk density of the order of 2 g / cm 3 (45% of space between the granules + 15% of porosity in the granules) is obtained.
  • the granules are placed in the part to be reinforced, which thus comprises 55% by volume of porous granules. After reaction, 55% by volume of zones with a high concentration of approximately 55% of globular titanium carbide, ie 30% by volume of global titanium carbide in the reinforced macro-microstructure of the grinding cone, are obtained in the reinforced part. .
  • millimetric granules which are crimped into the metal infiltration alloy. These millimetric granules are themselves composed of microscopic particles of globular TiC also crimped in the metal alloy infiltration. This system makes it possible to obtain a grinding cone with a reinforcing zone comprising a macrostructure within which there is an identical microstructure on a scale approximately a thousand times smaller.
  • the reinforcing zone of the grinding cone comprises small globular particles of titanium carbide, hard and finely dispersed in a metal matrix around them, avoids the formation and propagation of cracks (see Fig. 4 & 6 ). There is thus a double dissipative system of cracks.
  • Cracks generally originate at the most fragile places, which in this case are the TiC particle or the interface between this particle and the infiltration metal alloy. If a crack originates at the interface or in the micrometric particle of TiC, the propagation of this crack is then impeded by the infiltration alloy which surrounds this particle. The toughness of the infiltration alloy is greater than that of the TiC ceramic particle. The crack needs more energy to pass from one particle to another, to cross the micrometric spaces that exist between the particles.
  • the expansion coefficient of the TiC reinforcement is lower than that of the ferrous alloy matrix (TiC expansion coefficient: 7.5 ⁇ 10 -6 / K and the ferrous alloy: about 12.0 ⁇ 10 -6 / K).
  • This difference in the expansion coefficients has the consequence of generating tensions in the material during the solidification phase and also during the heat treatment. If these voltages are too great, cracks may appear in the room and lead to scrapping it.
  • a small proportion of TiC reinforcement (less than 50% by volume) is used, resulting in less stress in the part.
  • the presence of a more ductile matrix between the micrometric globular particles of TiC in alternating zones of low and high concentration makes it possible to better manage any local voltages.
  • the boundary between the reinforced portion and the unreinforced portion of the grinding cone is not abrupt because there is a continuity of the metal matrix between the reinforced portion and the unreinforced portion, thereby protect it against a complete tearing of the reinforcement.

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Abstract

The present invention discloses a composite milling cone for compression crushers, said milling cone comprising a ferrous alloy at least partially reinforced with titanium carbide according to a defined geometry, in which said reinforced portion comprises an alternating macro-microstructure of millimetric areas concentrated with micrometric globular particles of titanium carbide separated by millimetric areas (2) essentially free of micrometric globular particles of titanium carbide, said areas concentrated with micrometric globular particles of titanium carbide forming a microstructure in which the micrometric interstices between said globular particles are also filled by said ferrous alloy.

Description

Objet de l'inventionObject of the invention

La présente invention se rapporte à un cône de broyage composite pour concasseur à compression dans le domaine du concassage des roches dans les industries extractives telles que mines, carrières, cimenteries, etc., mais aussi dans l'industrie du recyclage, etc., ainsi qu'à un procédé de fabrication de tels cônes.The present invention relates to a composite grinding cone for compression crushers in the field of rock crushing in extractive industries such as mines, quarries, cement plants, etc., but also in the recycling industry, etc., as well as than a method of manufacturing such cones.

DéfinitionDefinition

Dans ce document, nous entendons par « concasseur à compression », des concasseurs à cône ou des concasseurs giratoires équipés de cônes de broyage constituant la principale pièce d'usure de ces machines.In this document, we mean by "compression crusher", cone crushers or gyratory crushers equipped with grinding cones constituting the main wear part of these machines.

Les concasseurs à cône ou les concasseurs giratoires, disposent d'une pièce d'usure en forme de cône, appelé cône de broyage. C'est de ce type de cône qu'il est question dans la présente demande de brevet. Le cône a pour fonction d'être au contact direct de la roche ou du matériau à broyer pendant la phase du procédé où de très importantes contraintes de compression sont appliquées à la matière à concasser.Cone crushers or gyratory crushers have a cone-shaped wear part called the grinding cone. This type of cone is the subject of this patent application. The cone has the function of being in direct contact with the rock or the material to be ground during the process phase, where very high compressive stresses are applied to the material to be crushed.

Les concasseurs à compression sont utilisées dans les premières étapes de la ligne de fabrication destinée à diminuer drastiquement la dimension de la roche, dans les industries extractives (mines, carrières, cimenteries, ...) et de recyclage.Compression crushers are used in the early stages of the production line to drastically reduce the size of the rock, in the extractive industries (mines, quarries, cement plants, ...) and recycling.

Etat de la techniqueState of the art

Peu de moyens sont connus pour modifier la dureté et la résistance à la compression d'un alliage de fonderie en profondeur « dans la masse ». Les moyens connus concernent généralement des modifications en surface de faible profondeur (quelques mm). Pour les pièces réalisées en fonderie, les éléments de renfort doivent être présents en profondeur afin de résister à des sollicitations localisées importantes et simultanées en termes de contraintes mécaniques (usure, compression, impact) pour limiter l'usure et donc la consommation de la pièce pendant sa durée de vie.Few means are known for modifying the hardness and compressive strength of a foundry alloy at depth "in the mass". The known means generally concern surface modifications of shallow depth (a few mm). For foundry parts, reinforcing elements must be present in depth in order to withstand significant and simultaneous localized stress in terms of mechanical stress (wear, compression, impact) to limit wear and therefore the consumption of the part during its lifetime.

Le document US 5,516,053 (Hannu ) décrit une méthode d'amélioration des performances des cônes de broyage pour les concasseurs à cône, basée sur une technique de rechargement utilisant des particules dures comme du carbure de tungstène ; cette technique ne produit ses effets qu'en surface et sur une épaisseur relativement limitée.The document US5,516,053 (Hannu ) describes a method of improving the performance of grinding cones for cone crushers, based on a reloading technique using hard particles such as tungsten carbide; this technique produces its effects only on the surface and on a relatively limited thickness.

Le document JP 53 17731 propose une solution qui consiste à alterner des zones plus résistantes et moins résistantes à l'usure, dans le sens de la génératrice d'un cône de broyage. Cette technique a pour effet de générer à la surface du cône un relief qui serait favorable à l'allongement de la durée de vie de la pièce.The document JP 53 17731 proposes a solution that consists of alternating zones that are more resistant and less resistant to wear, in the direction of the generator of a grinding cone. This technique has the effect of generating on the surface of the cone a relief that would be favorable to the extension of the service life of the part.

Le document US 6,123,279 (Stafford ) propose de renforcer les surfaces des cônes et des mâchoires en acier au manganèse au moyen d'inserts en carbure de tungstène qui sont introduits et fixés mécaniquement dans des logements prévus à cet effet; cette solution a pour résultat un renforcement discontinu de la surface de la pièce.The document US 6,123,279 (Stafford ) proposes to reinforce the surfaces of manganese steel cones and jaws by means of tungsten carbide inserts which are introduced and mechanically fixed in housings provided for that purpose; this solution results in a discontinuous reinforcement of the surface of the workpiece.

Le document WO 2007/138162 (Hellman ) décrit une méthode de fabrication d'un cône faisant appel à des matériaux composites.The document WO 2007/138162 (Hellman ) describes a method of making a cone using composite materials.

Le document US 2008/041995 (Hall ) prévoit de renforcer la surface travaillante d'un cône avec des inserts en matériaux durs.The document US 2008/041995 (Hall ) plans to reinforce the working surface of a cone with inserts made of hard materials.

Buts de l'inventionGoals of the invention

La présente invention divulgue un cône de broyage composite pour concasseurs à compression présentant une résistance améliorée contre l'usure tout en maintenant une bonne résistance aux chocs. Cette propriété est obtenue par une structure composite de renforcement spécifiquement conçue pour cette application, matériau qui fait alterner à l'échelle millimétrique des zones denses en fines particules globulaires micrométriques de carbures métalliques avec des zones qui en sont pratiquement exemptes au sein de la matrice métallique du cône de broyage.The present invention discloses a composite grinding cone for compression crushers having improved wear resistance while maintaining good impact resistance. This property is obtained by a composite reinforcement structure specifically designed for this application, a material that alternates on a millimeter scale dense zones in fine micrometric globular particles of metal carbides with zones that are practically free of them within the metallic matrix. grinding cone.

La présente invention propose également un procédé pour l'obtention de ladite structure de renforcement.The present invention also provides a method for obtaining said reinforcing structure.

Résumé de l'inventionSummary of the invention

La présente invention divulgue un cône de broyage composite pour concasseurs à compression, ledit cône de broyage comportant un alliage ferreux renforcé au moins en partie avec du carbure de titane selon une géométrie définie, dans lequel ladite partie renforcée comporte une macro-microstructure alternée de zones millimétriques concentrées en particules globulaires micrométriques de carbure de titane séparées par des zones millimétriques essentiellement exemptes de particules globulaires micrométriques de carbure de titane, lesdites zones concentrées en particules globulaires micrométriques de carbure de titane formant une microstructure dans laquelle les interstices micrométriques entre lesdites particules globulaires sont également occupés par ledit alliage ferreux.The present invention discloses a composite grinding cone for compression crushers, said grinding cone comprising a ferrous alloy reinforced at least in part with titanium carbide according to a defined geometry, wherein said reinforced portion comprises an alternating macro-microstructure of zones millimeters concentrated in micrometric globular particles of titanium carbide separated by millimetric zones essentially free of micrometric globular particles of titanium carbide, said zones concentrated in micrometric globular particles of titanium carbide forming a microstructure in which the micrometric interstices between said globular particles are also occupied by said ferrous alloy.

Selon des modes particuliers de l'invention, le cône de broyage composite comporte au moins une ou une combinaison appropriée des caractéristiques suivantes :

  • lesdites zones millimétriques concentrées ont une concentration en carbures de titane supérieure à 36.9 % en volume ;
  • ladite partie renforcée a une teneur globale de carbure de titane entre 16.6 et 50.5 % en volume ;
  • les particules micrométriques globulaires de carbure de titane ont une taille inférieure à 50µm ;
  • la majeure partie des particules micrométriques globulaires de carbure de titane a une taille inférieure à 20 µm ;
  • lesdites zones concentrées en particules globulaires de carbure de titane comportent 36.9 à 72.2 % en volume de carbure de titane ;
  • lesdites zones millimétriques concentrées en carbure de titane ont une dimension variant de 1 à 12 mm ;
  • lesdites zones millimétriques concentrées en carbure de titane ont une dimension variant de 1 à 6 mm ;
  • lesdites zones concentrées en carbure de titane ont une dimension variant de 1.4 à 4 mm.
According to particular embodiments of the invention, the composite grinding cone comprises at least one or a suitable combination of the following characteristics:
  • said concentrated millimeter areas have a concentration of titanium carbides greater than 36.9% by volume;
  • said reinforced portion has an overall titanium carbide content between 16.6 and 50.5% by volume;
  • the micrometric globular particles of titanium carbide have a size of less than 50 μm;
  • most of the micrometric globular particles of titanium carbide has a size less than 20 microns;
  • said zones concentrated in globular particles of titanium carbide comprise 36.9 to 72.2% by volume of titanium carbide;
  • said millimetric areas of concentrated titanium carbide have a size ranging from 1 to 12 mm;
  • said millimetric zones concentrated in titanium carbide have a dimension ranging from 1 to 6 mm;
  • said concentrated areas of titanium carbide have a dimension ranging from 1.4 to 4 mm.

La présente invention divulgue également un procédé de fabrication du cône de broyage composite selon l'une quelconque des revendications 1 à 9 comportant les étapes suivantes:

  • mise à disposition d'un moule comportant l'empreinte du cône de broyage avec une géométrie de renforcement prédéfinie ;
  • introduction, dans la partie de l'empreinte du cône de broyage destiné à former la partie renforcée (5), d'un mélange de poudres compactées comportant du carbone et du titane sous forme de granulés millimétriques précurceurs de carbure de titane ;
  • coulée d'un alliage ferreux dans le moule, la chaleur de ladite coulée déclenchant une réaction exothermique de synthèse auto-propagée de carbure de titane à haute température (SHS) au sein desdits granulés précurseurs ;
  • formation, au sein de la partie renforcée du cône de broyage composite d'une macro-microstructure alternée de zones millimétriques concentrées en particules globulaires micrométriques de carbure de titane à l'emplacement desdits granulés précurseurs, lesdites zones étant séparées entre elles par des zones millimétriques essentiellement exemptes de particles globulaires micrométriques de carbure de titane, lesdites particules globulaires étant également séparées au sein desdites zones millimétriques concentrées de carbure de titane par des interstices micrométriques ;
  • infiltration des interstices millimétriques et micrométriques par ledit alliage ferreux de coulée à haute température, consécutive à la formation de particules microscopiques globulaires de carbure de titane.
The present invention also discloses a method of manufacturing the composite grinding cone according to any one of claims 1 to 9 comprising the following steps:
  • providing a mold having the impression of the grinding cone with a predefined reinforcement geometry;
  • introducing, into the portion of the cavity of the grinding cone for forming the reinforced portion (5), a mixture of compacted powders comprising carbon and titanium in the form of millimetric granules precursors of titanium carbide;
  • casting a ferrous alloy into the mold, the heat of said casting triggering an exothermic reaction of self-propagating synthesis of high temperature titanium carbide (SHS) within said precursor granules;
  • forming, within the reinforced portion of the composite grinding cone, an alternating macro-microstructure of millimetric zones concentrated in micrometric globular particles of titanium carbide at the location of said precursor granules, said zones being separated from each other by millimetric zones essentially free of micrometric globular particles of titanium carbide, said globular particles being also separated within said millimetric areas of concentrated titanium carbide by micrometric interstices;
  • infiltration of the millimetric and micrometric interstices by said high-temperature ferrous casting alloy, subsequent to the formation of microscopic globular particles of titanium carbide.

Selon des modes particuliers de l'invention, le procédé comporte au moins une ou une combinaison appropriée des caractéristiques suivantes :

  • les poudres compactées de titane et de carbone comportent une poudre d'un alliage ferreux ;
  • ledit carbone est du graphite.
According to particular embodiments of the invention, the method comprises at least one or a suitable combination of the following characteristics:
  • the compacted powders of titanium and carbon comprise a powder of a ferrous alloy;
  • said carbon is graphite.

La présente invention divulgue également un cône de broyage composite obtenu selon le procédé de l'une quelconque des revendications 11 à 13.The present invention also discloses a composite grinding cone obtained by the method of any one of claims 11 to 13.

Brève description des figuresBrief description of the figures

Les figures 1 et 2 montrent une vue globale en trois dimensions des différents types de machines dans lesquelles sont utilisés des cônes de broyage selon la présente invention.The Figures 1 and 2 show an overall three-dimensional view of the different types of machines in which grinding cones according to the present invention are used.

La figure 3 montre une vue en trois dimensions d'un cône de broyage et la manière dont le(s) renforcement(s) peu(ven)t être disposé(s) de manière à atteindre le but recherché. (géométrie de renforcement)The figure 3 shows a three-dimensional view of a grinding cone and how the reinforcement (s) can be arranged to achieve the desired purpose. (reinforcement geometry)

La figure 4a-4h représente schématiquement le procédé de fabrication d'un cône selon l'invention.

  • l'étape 4a montre le dispositif de mélange des poudres de titane et de carbone ;
  • l'étape 4b montre la compaction des poudres entre deux rouleaux suivie d'un concassage et d'un tamisage avec recyclage des particules trop fines ;
  • la figure 4c montre un moule de sable dans lequel on a placé un barrage pour contenir les granulés de poudre compactée à l'endroit du renforcement de la barre de blindage pour le concasseur à mâchoire ;
  • la figure 4d montre un agrandissement de la zone de renforcement dans laquelle se trouvent les granulés compactés comportant les réactifs précurseurs du TiC ;
  • l'étape 4e montre la coulée de l'alliage ferreux dans le moule ;
  • la figure 4f montre schématiquement un cône de broyage qui est le résultat de la coulée ;
  • la figure 4g montre un agrandissement des zones à forte concentration en nodules de TiC ;
  • la figure 4h montre un agrandissement au sein d'une même zone à forte concentration en nodules de TiC. Les nodules micrométriques sont individuellement entourés par le métal de coulée.
FIG. 4a-4h schematically represents the process for manufacturing a cone according to the invention.
  • step 4a shows the device for mixing titanium and carbon powders;
  • step 4b shows the compaction of the powders between two rollers followed by crushing and sieving with recycling of the fine particles;
  • the figure 4c shows a sand mold in which a dam has been placed to contain the compacted powder granules at the reinforcement point of the armor bar for the jaw crusher;
  • the figure 4d shows an enlargement of the reinforcement zone in which the compacted granules comprising TiC precursor reactants are located;
  • step 4e shows the casting of the ferrous alloy in the mold;
  • the figure 4f schematically shows a grinding cone that is the result of casting;
  • the figure 4g shows an enlargement of areas with high concentrations of TiC nodules;
  • the figure 4h shows an enlargement within the same zone with a high concentration of TiC nodules. The micrometric nodules are individually surrounded by the casting metal.

La figure 5 représente une vue au binoculaire d'une surface polie, non attaquée, d'une coupe de la partie renforcée d'un cône selon l'invention avec des zones millimétriques (en gris clair) concentrées en carbure de titane globulaire micrométrique (nodules de TiC). La partie sombre représente la matrice métallique (acier ou fonte) remplissant à la fois l'espace entre ces zones concentrées en carbure de titane globulaire micrométrique mais aussi les espaces entre les globules eux-mêmes.The figure 5 represents a binocular view of a polished, unengaged surface of a section of the reinforced portion of a cone according to the invention with millimetric zones (in light gray) concentrated micrometric globular titanium carbide (TiC nodules) ). The dark part represents the metal matrix (steel or cast iron) filling at the same time the space between these concentrated zones in micrometric globular titanium carbide but also the spaces between the globules themselves.

Les figures 6 et 7 représentent des vues prises au microscope électronique SEM de carbure de titane globulaire micrométrique sur des surfaces polies et non attaquées à des grossissements différents. On voit que dans ce cas particulier la plupart des globules de carbure de titane ont une taille inférieure à 10 µm.The figures 6 and 7 represent SEM electron microscopic views of micrometric globular titanium carbide on polished and untouched surfaces at different magnifications. We see that in this particular case most of the globules of titanium carbide have a size less than 10 microns.

La figure 8 représente une vue de carbure de titane globulaire micrométrique sur une surface de rupture prise au microscope électronique SEM. On voit que les globules de carbure de titane sont parfaitement incorporés dans la matrice métallique. Ceci prouve que le métal de coulée infiltre (imprègne) complètement les pores lors de la coulée une fois que la réaction chimique entre le titane et le carbone est initiée.The figure 8 represents a view of micrometric globular titanium carbide on a fracture surface taken by SEM electron microscope. It can be seen that the globules of titanium carbide are perfectly incorporated in the metal matrix. This proves that the casting metal completely infiltrates (impregnates) the pores during casting once the chemical reaction between titanium and carbon is initiated.

LégendeLegend

  1. 1. zones millimétriques concentrées en particules globulaires (nodules) micrométriques de carbure de titane1. Millimeter areas concentrated in micrometric globular particles (nodules) of titanium carbide
  2. 2. interstices millimétriques remplis par l'alliage de coulée globalement exempts de particules globulaires micrométriques de carbure de titane2. millimetric interstices filled with the casting alloy generally free of micrometric globular particles of titanium carbide
  3. 3. interstices micrométriques entre les nodules de TiC également infiltrés par l'alliage de coulée3. micrometric interstices between TiC nodules also infiltrated by casting alloy
  4. 4. carbure de titane globulaire micrométrique, dans les zones concentrées en carbure de titane4. micrometric globular titanium carbide, in the concentrated areas of titanium carbide
  5. 5. renfort de carbure de titane5. titanium carbide reinforcement
  6. 6. défauts de gaz6. gas defects
  7. 7. cône avec renforcement selon l'invention7. cone with reinforcement according to the invention
  8. 8. mélangeur de poudres de Ti et de C8. mixer of Ti and C powders
  9. 9. trémie9. hopper
  10. 10. rouleau10. roll
  11. 11. broyeur11. crusher
  12. 12. grille de sortie12. exit grid
  13. 13. tamis13. sieve
  14. 14. recyclage des particules trop fines vers la trémie14. recycling of fine particles to the hopper
  15. 15. moule de sable15. sand mold
  16. 16. barrage contenant les granulés compactés de mélange Ti/C16. dam containing the compacted granules of Ti / C mixture
  17. 17. poche de coulée17. ladle
  18. 18. cône (schématique)18. cone (schematic)
Description détaillée de l'inventionDetailed description of the invention

En science des matériaux, on appelle réaction SHS ou « self-propagating high temperature synthesis », une réaction de synthèse à haute température auto-propagée où l'on atteint des températures de réaction généralement supérieures à 1500°C, voire 2000°C. Par exemple, la réaction entre de la poudre de titane et de la poudre de carbone pour obtenir le carbure de titane TiC, est fortement exothermique. On a uniquement besoin d'un peu d'énergie pour initier localement la réaction. Ensuite, la réaction se propagera spontanément à la totalité du mélange des réactifs grâce aux hautes températures atteintes. Après initiation de la réaction, on a un front de réaction qui se propage ainsi spontanément (auto-propagée) et qui permet l'obtention du carbure de titane à partir du titane et du carbone. Le carbure de titane ainsi obtenu est dit « obtenu in situ » car il ne provient pas de l'alliage ferreux coulé.In materials science, the SHS or " s elf-propagating h igh temperature s ynthesis" reaction is a self-propagating, high-temperature synthesis reaction in which reaction temperatures are generally greater than 1500 ° C or even 2000. ° C. For example, the reaction between titanium powder and carbon powder to obtain titanium carbide TiC is highly exothermic. Only a little energy is needed to initiate the reaction locally. Then, the reaction will spontaneously propagate to the entire mixture of reagents thanks to the high temperatures reached. After initiation of the reaction, there is a reaction front which propagates spontaneously (self-propagated) and which makes it possible to obtain titanium carbide from titanium and carbon. The titanium carbide thus obtained is said to be "obtained in situ because it does not come from the cast ferrous alloy.

Les mélanges de poudres de réactif comportent de la poudre de carbone et de la poudre de titane et sont comprimés en plaques et ensuite concassés afin d'obtenir des granulés dont la taille varie de 1 à 12 mm, de préférence de 1 à 6 mm, et de manière particulièrement préférée de 1.4 à 4 mm. Ces granulés ne sont pas compactés à 100 %. On les comprime généralement entre 55 et 95 % de la densité théorique. Ces granulés permettent une utilisation/manipulation aisée (voir Fig. 3a-3h).The reactant powder mixtures comprise carbon powder and titanium powder and are compressed into plates and then crushed to obtain granules ranging in size from 1 to 12 mm, preferably from 1 to 6 mm, and particularly preferably from 1.4 to 4 mm. These granules are not 100% compacted. They are generally compressed between 55 and 95% of the theoretical density. These granules allow easy use / handling (see Fig. 3a-3h).

Ces granulés millimétriques de poudres de carbone et de titane mélangées obtenus selon les schémas de la figure 4a-4h constituent les précurseurs du carbure de titane à créer et permettent de remplir facilement des parties de moules de formes diverses ou irrégulières. Ces granulés peuvent être maintenus en place dans le moule 15 à l'aide d'un barrage 16, par exemple. La mise en forme ou l'assemblage de ces granulés peut également se faire à l'aide d'une colle.These millimetric granules of mixed carbon and titanium powders obtained according to the diagrams of FIG. 4a-4h constitute the precursors of the titanium carbide to be created and make it possible to easily fill mold parts of various or irregular shapes. These granules can be held in place in the mold 15 by means of a dam 16, for example. The shaping or assembly of these granules can also be done using an adhesive.

Le cône de broyage composite selon la présente invention possède une macro-microstructure de renforcement que l'on peut encore appeler structure alternée de zones concentrées en particules micrométriques globulaires de carbure de titane séparées par des zones qui en sont pratiquement exemptes. Une telle structure est obtenue par la réaction dans le moule 15 des granulés comportant un mélange de poudres de carbone et de titane. Cette réaction est initiée par la chaleur de la coulée de la fonte ou de l'acier utilisés pour couler toute la pièce et donc à la fois la partie non renforcée et la partie renforcée (voir Fig. 3e). La coulée déclenche donc une réaction exothermique de synthèse auto-propagée à haute température du mélange de poudres de carbone et de titane compactées sous forme de granulés (self-propagating high-temperature synthesis - SHS) et préalablement placées dans le moule 15. La réaction a alors la particularité de continuer à se propager dès qu'elle est initiée.The composite grinding cone according to the present invention has a reinforcing macro-microstructure which may alternatively be called an alternating structure of concentrated micrometric globular particles of titanium carbide separated by zones which are substantially free of it. Such a structure is obtained by the reaction in the mold of the granules comprising a mixture of powders of carbon and titanium. This reaction is initiated by the heat of casting of the cast iron or steel used to pour the whole piece and thus both the unreinforced part and the reinforced part (see Fig. 3e). The casting therefore triggers an exothermic synthesis reaction self-propagated at high temperature of the mixture of powders of carbon and titanium compacted in the form of granules (self-propagating high-temperature synthesis - SHS) and previously placed in the mold 15. The reaction then has the distinction of continuing to spread as soon as it is initiated.

Cette synthèse à haute température (SHS) permet une infiltration aisée de tous les interstices millimétriques et micrométriques par la fonte ou l'acier de coulée (Fig. 4g & 4h). En augmentant la mouillabilité, l'infiltration peut se faire sur n'importe quelle épaisseur ou profondeur de renforcement du cône de broyage. Elle permet avantageusement de créer, après réaction SHS et infiltration par un métal de coulée extérieur, une ou plusieurs zones de renfort sur le cône de broyage comportant une forte concentration de particules globulaires micrométriques de carbure de titane (que l'on pourrait encore appeler des clusters de nodules), lesquelles zones ayant une taille de l'ordre du millimètre ou de quelques millimètres, et qui alternent avec des zones substantiellement exemptes de carbure de titane globulaire.This high temperature synthesis (SHS) allows easy infiltration of all millimetric and micrometric interstices by cast iron or casting steel ( Fig. 4g & 4h ). By increasing the wettability, the infiltration can be done on any thickness or depth of reinforcement of the grinding cone. It advantageously makes it possible, after SHS reaction and infiltration by an external casting metal, to create one or more reinforcement zones on the grinding cone comprising a high concentration of micrometric globular particles of titanium carbide (which could also be called clusters of nodules), which areas have a size of the order of a millimeter or a few millimeters, and which alternate with areas substantially free of globular titanium carbide.

Une fois que ces granulés ont réagi selon une réaction SHS, les zones de renforcement où se trouvaient ces granulés montrent une dispersion concentrée de particules globulaires micrométriques 4 de carbure TiC (globules) dont les interstices micrométriques 3 ont été également infiltrés par le métal de coulée qui est ici de la fonte ou de l'acier. Il est important de remarquer que les interstices millimétriques et micrométriques sont infiltrés par la même matrice métallique que celle qui constitue la partie non renforcée du cône de broyage; ceci permet une liberté totale de choix du métal de coulée. Dans le cône de broyage finalement obtenu, les zones de renfort à forte concentration de carbure de titane sont composées de particules micrométriques globulaires de TiC en pourcentage important (entre environ 35 et environ 70 % en volume) et de l'alliage ferreux d'infiltration.Once these granules have reacted according to an SHS reaction, the zones of reinforcement where these granules were found show a concentrated dispersion of micrometric globular particles 4 of TiC carbide (globules) whose micrometric interstices 3 have also been infiltrated by the casting metal. which is here cast iron or steel. It is important to note that the millimetric and micrometric interstices are infiltrated by the same metal matrix as that which constitutes the unreinforced part of the grinding cone; this allows a total freedom of choice of the casting metal. In the grinding cone finally obtained, the reinforcement zones with a high concentration of titanium carbide are composed of globular micrometric particles of TiC in significant percentage (between about 35 and about 70% by volume) and the ferrous alloy infiltration.

Par particules globulaires micrométriques, il faut entendre des particules globalement sphéroïdales qui ont une taille allant du µm à quelques dizaines de µm tout au plus, la grande majorité de ces particules ayant une taille inférieure à 50 µm, et même à 20 µm, voire à 10 µm. Nous les appelons également des globules de TiC. Cette forme globulaire est caractéristique d'une méthode d'obtention du carbure de titane par synthèse auto-propagée SHS (voir Fig. 7).Micrometric globular particles are understood to mean globally spheroidal particles having a size ranging from a few μm to a few tens of μm at the most, the vast majority of these particles having a size of less than 50 μm, and even 20 μm, or even less than 10 μm. We also call them TiC globules. This globular form is characteristic of a method for obtaining titanium carbide by self-propagating synthesis SHS (see Fig. 7 ).

Obtention des granulés (version Ti + C) pour le renforcement du cône de broyageObtaining granules (Ti + C version) for reinforcing the grinding cone

Le procédé d'obtention des granulés est illustré à la figure 4a-4h. Les granulés de réactifs carbone/titane sont obtenus par compaction entre des rouleaux 10 afin d'obtenir des bandes que l'on concasse ensuite dans un concasseur 11. Le mélange des poudres est fait dans un mélangeur 8 constitué d'une cuve munie de pales, afin de favoriser l'homogénéité. Le mélange passe ensuite dans un appareil de granulation par une trémie 9. Cette machine comprend deux rouleaux 10, au travers desquels on fait passer la matière. Une pression est appliquée sur ces rouleaux 10, ce qui permet de comprimer la matière. On obtient à la sortie une bande de matière comprimée qui est ensuite concassée afin d'obtenir les granulés. Ces granulés sont ensuite tamisés à la granulométrie souhaitée dans un tamis 13. Un paramètre important est la pression appliquée sur les rouleaux. Au plus cette pression est élevée, au plus la bande, et donc les granulés seront comprimés. On peut ainsi faire varier la densité des bandes, et par conséquent des granulés, entre 55 et 95 % de la densité théorique qui est de 3.75 g/cm3 pour le mélange stoechiométrique de titane et de carbone. La densité apparente (tenant compte de la porosité) se situe alors entre 2.06 et 3.56 g/cm3.The process for obtaining the granules is illustrated in FIG. 4a-4h. The granules of carbon / titanium reagents are obtained by compaction between rollers 10 in order to obtain strips that are then crushed in a crusher 11. The mixture of the powders is made in a mixer 8 consisting of a tank equipped with blades , to promote homogeneity. The mixture then passes into a granulation apparatus through a hopper 9. This machine comprises two rollers 10, through which the material is passed. Pressure is applied to these rollers 10, which compresses the material. A strip of compressed material is obtained at the outlet, which is then crushed in order to obtain the granules. These granules are then sieved to the desired particle size in a sieve 13. An important parameter is the pressure applied to the rollers. At most this pressure is high, the more the band, and therefore the granules will be compressed. It is thus possible to vary the density of the strips, and consequently the granules, between 55 and 95% of the theoretical density which is 3.75 g / cm 3 for the stoichiometric mixture of titanium and carbon. The apparent density (taking into account the porosity) is then between 2.06 and 3.56 g / cm 3 .

Le degré de compaction des bandes dépend de la pression appliquée (en Pa) sur les rouleaux (diamètre 200 mm, largeur 30 mm). Pour un bas niveau de compaction, de l'ordre de 106 Pa, on obtient une densité sur les bandes de l'ordre de 55 % de la densité théorique. Après le passage à travers les rouleaux 10 pour comprimer cette matière, la densité apparente des granulés est de 3.75 x 0.55, soit 2.06 g/cm3.The degree of compaction of the bands depends on the applied pressure (in Pa) on the rollers (diameter 200 mm, width 30 mm). For a low level of compaction, of the order of 10 6 Pa, we obtain a density on the bands of the order of 55% of the theoretical density. After passing through the rollers 10 to compress this material, the apparent density of the granules is 3.75 x 0.55, ie 2.06 g / cm 3 .

Pour un haut niveau de compaction, de l'ordre de 25.106 Pa, on obtient une densité sur les bandes de 90 % de la densité théorique, soit une densité apparente de 3.38 g/cm3. En pratique on peut aller jusqu'à 95 % de la densité théorique.For a high level of compaction, of the order of 25 × 10 6 Pa, a density on the strips of 90% of the theoretical density is obtained, ie a bulk density of 3.38 g / cm 3 . In practice one can go up to 95% of the theoretical density.

Par conséquent, les granulés obtenus à partir de la matière première Ti + C sont poreux. Cette porosité varie de 5 % pour les granulés très fortement comprimés, à 45 % pour les granulés faiblement comprimés.Therefore, the granules obtained from the raw material Ti + C are porous. This porosity varies from 5% for highly compressed granules, to 45% for slightly compressed granules.

Outre le niveau de compaction, il est également possible de régler la répartition granulométrique des granulés ainsi que leur forme lors de l'opération de concassage des bandes et de tamisage des granulés de Ti+C. On recycle à volonté les fractions granulométriques non désirées (voir Fig. 4b). Les granulés obtenus ont globalement une taille entre 1 et 12 mm, de préférence entre 1 et 6 mm, et de manière particulièrement préférée entre 1.4 et 4 mm.In addition to the level of compaction, it is also possible to adjust the granulometric distribution of the granules and their shape during the operation of crushing strips and sieving Ti + C granules. Unwanted particle size fractions are recycled at will (see Fig. 4b ). The granules obtained generally have a size between 1 and 12 mm, preferably between 1 and 6 mm, and particularly preferably between 1.4 and 4 mm.

Réalisation de la zone de renfort dans le cône de broyage composite selon inventionRealization of the reinforcement zone in the composite grinding cone according to the invention

Les granulés sont réalisés comme exposé ci-dessus. Pour obtenir une structure tridimensionnelle ou superstructure/macro-microstructure avec ces granulés, on les dispose dans les zones du moule où l'on souhaite renforcer la pièce. Ceci est réalisé en agglomérant les granulés soit au moyen d'une colle, soit en les confinant dans un récipient, ou par tout autre moyen (barrage 16).
La densité en vrac de l'empilement des granulés de Ti + C est mesurée selon la norme ISO 697 et dépend du niveau de compaction des bandes, de la répartition granulométrique des granulés et du mode de concassage des bandes, qui influence la forme des granulés.
La densité en vrac de ces granulés de Ti + C est généralement de l'ordre de 0.9 g/cm3 à 2.5 g/cm3 en fonction du niveau de compaction de ces granulés et de la densité de l'empilement.The granules are made as described above. To obtain a three-dimensional structure superstructure / macro-microstructure with these granules, they are available in the areas of the mold where it is desired to reinforce the part. This is achieved by agglomerating the granules either by means of an adhesive, or by confining them in a container, or by any other means (dam 16).
The bulk density of the stack of Ti + C granules is measured according to ISO 697 and depends on the level of compaction of the bands, the granulometric distribution of the granules and the crushing mode of the bands, which influences the shape of the granules .
The bulk density of these Ti + C granules is generally of the order of 0.9 g / cm 3 to 2.5 g / cm 3 depending on the level of compaction of these granules and the density of the stack.

Avant réaction, on a donc un empilement de granulés poreux composés d'un mélange de poudre de titane et de poudre de carbone.Before reaction, there is therefore a stack of porous granules composed of a mixture of titanium powder and carbon powder.

Lors de la réaction Ti + C → TiC, il se produit une contraction volumétrique de l'ordre de 24 % quand on passe des réactifs au produit (contraction venant de la différence de densité entre les réactifs et les produits). Ainsi, la densité théorique du mélange Ti + C est de 3.75 g/cm3 et la densité théorique du TiC est de 4.93 g/cm3. Dans le produit final, après la réaction d'obtention du TiC, le métal de coulée infiltrera :

  • la porosité microscopique présente dans les espaces à forte concentration en carbure de titane, dépendant du niveau de compaction initial de ces granulés ;
  • les espaces millimétriques entre les zones à forte concentration en carbure de titane, dépendant de l'empilement initial des granulés (densité en vrac) ;
  • la porosité venant de la contraction volumétrique lors de la réaction entre Ti + C pour obtenir le TiC.
During the Ti + C → TiC reaction, there is a volumetric contraction of about 24% when passing reagents to the product (contraction coming from the density difference between the reagents and the products). Thus, the theoretical density of the Ti + C mixture is 3.75 g / cm 3 and the theoretical density of the TiC is 4.93 g / cm 3 . In the final product, after the reaction to obtain TiC, the casting metal will infiltrate:
  • the microscopic porosity present in spaces with a high concentration of titanium carbide, depending on the initial level of compaction of these granules;
  • the millimeter spaces between the zones with a high concentration of titanium carbide, depending on the initial stacking of the granules (bulk density);
  • the porosity coming from the volumetric contraction during the reaction between Ti + C to obtain the TiC.

ExemplesExamples

Dans les exemples qui suivent, on a utilisé les matières premières suivantes :
- titane, H.C. STARCK, Amperit 155.066, moins de 200 mesh,
- carbone graphite GK Kropfmuhl, UF4, > 99.5 %, moins de 15 µm,
- Fe, sous la forme Acier HSS M2, moins de 25 µm,
- proportions : - Ti + C 100 g Ti - 24.5 g C - Ti + C + Fe 100 g Ti - 24.5 g C - 35.2 g Fe Mélange 15 min dans mélangeur Lindor, sous argon.
La granulation, a été effectuée avec un granulateur Sahut-Conreur.
Pour les mélanges Ti+C+Fe et Ti+C, la compacité des granulés a été obtenue en faisant varier la pression entre les rouleaux de 10 à 250.105 Pa.
Le renforcement a été effectué en plaçant des granulés dans un container métallique, qui est ensuite judicieusement placé dans le moule à l'endroit où le cône de broyage est susceptible d'être renforcé. Ensuite on coule l'acier ou la fonte dans ce moule.In the examples that follow, the following raw materials were used:
titanium, HC STARCK, Amperit 155.066, less than 200 mesh,
- graphite carbon GK Kropfmuhl, UF4,> 99.5%, less than 15 μm,
Fe, in the form of HSS M2 steel, less than 25 μm,
- proportions: - Ti + C 100 g Ti - 24.5 g C - Ti + C + Fe 100 g Ti - 24.5 g C - 35.2 g Fe Mix 15 min in Lindor mixer, under argon.
Granulation was carried out with a Sahut-Conreur granulator.
For the Ti + C + Fe and Ti + C mixtures, the compactness of the granules was obtained by varying the pressure between the rolls by 10 to 250 × 10 5 Pa.
Reinforcement has been done by placing granules in a metal container, which is then conveniently placed in the mold where the grinding cone is likely to be reinforced. Then we cast the steel or cast in this mold.

Exemple 1Example 1

Dans cet exemple, on vise à réaliser un cône de broyage dont les zones renforcées comportent un pourcentage en volume global de TiC d'environ 42 %. A cette fin, on réalise une bande par compaction à 85 % de la densité théorique d'un mélange de C et de Ti. Après concassage, les granulés sont tamisés de manière à obtenir une dimension de granulés située entre 1.4 et 4 mm. On obtient une densité en vrac de l'ordre de 2.1 g/cm3 (35 % d'espace entre les granulés + 15 % de porosité dans les granulés).In this example, it is intended to provide a grinding cone whose reinforced areas comprise an overall volume percentage of TiC of about 42%. For this purpose, a band is produced by compaction at 85% of the theoretical density of a mixture of C and Ti. After crushing, the granules are sieved to obtain a pellet size of between 1.4 and 4 mm. A bulk density of the order of 2.1 g / cm 3 (35% of space between the granules + 15% of porosity in the granules) is obtained.

On dispose les granulés dans le moule à l'endroit de la partie à renforcer qui comporte ainsi 65 % en volume de granulés poreux. On coule ensuite une fonte au chrome (3 % C, 25 % Cr) à environ 1500°C dans un moule en sable non préchauffé. La réaction entre le Ti et le C est initiée par la chaleur de la fonte. Cette coulée se fait sans atmosphère de protection. Après réaction, on obtient dans la partie renforcée 65 % en volume de zones avec une forte concentration d'environ 65 % en carbure de titane globulaire, soit 42 % en volume global de TiC dans la partie renforcée du cône de broyage.The granules are placed in the mold at the location of the part to be reinforced, which thus comprises 65% by volume of porous granules. A chromium cast iron (3% C, 25% Cr) was then cast at about 1500 ° C in a non-preheated sand mold. The reaction between Ti and C is initiated by the heat of melting. This casting is done without a protective atmosphere. After reaction, 65% by volume of zones with a high concentration of approximately 65% of globular titanium carbide are obtained in the reinforced part, ie 42% by global volume of TiC in the reinforced part of the grinding cone.

Exemple 2Example 2

Dans cet exemple, on vise à réaliser un cône de broyage dont les zones renforcées comportent un pourcentage en volume global de TiC d'environ 30 %. A cette fin, on réalise une bande par compaction à 70 % de la densité théorique d'un mélange de C et de Ti. Après concassage, les granulés sont tamisés de manière à obtenir une dimension de granulés située entre 1.4 et 4 mm. On obtient une densité en vrac de l'ordre de 1.4 g/cm3 (45 % d'espace entre les granulés + 30 % de porosité dans les granulées). On dispose les granulés dans la partie à renforcer qui comporte ainsi 55 % en volume de granulés poreux. Après réaction, on obtient, dans la partie renforcée, 55 % en volume de zones avec une forte concentration d'environ 53 % en carbure de titane globulaire, soit environ 30 % en volume global de TiC dans la partie renforcée du cône de broyage.In this example, it is intended to achieve a grinding cone whose reinforced areas comprise a global volume percentage of TiC of about 30%. For this purpose, a 70% compaction band is made of the theoretical density of a mixture of C and Ti. After crushing, the granules are sieved to obtain a pellet size of between 1.4 and 4 mm. A bulk density of the order of 1.4 g / cm 3 (45% of space between the granules + 30% of porosity in the granules) is obtained. The granules are placed in the part to be reinforced, which thus comprises 55% by volume of porous granules. After reaction, in the reinforced part, 55% by volume of zones with a high concentration of approximately 53% of globular titanium carbide, ie approximately 30% by volume of TiC in the reinforced portion of the grinding cone, are obtained.

Exemple 3Example 3

Dans cet exemple, on vise à réaliser un cône de broyage dont les zones renforcées comportent un pourcentage en volume global de TiC d'environ 20 %. A cette fin, on réalise une bande par compaction à 60 % de la densité théorique d'un mélange de C et de Ti. Après concassage, les granulés sont tamisés de manière à obtenir une dimension de granulés située entre 1 et 6 mm. On obtient une densité en vrac de l'ordre de 1.0 g/cm3 (55 % d'espace entre les granulés + 40 % de porosité dans les granulés). On dispose les granulés dans la partie à renforcer qui comporte ainsi 45 % en volume de granulés poreux. Après réaction, on obtient dans la partie renforcée 45 % en volume de zones concentrées à environ 45 % en carbure de titane globulaire, soit 20 % en volume global de TiC dans la partie renforcée du cône de broyage.In this example, it is intended to provide a grinding cone whose reinforced areas comprise a global volume percentage of TiC of about 20%. At this In the end, a 60% compaction band is made of the theoretical density of a mixture of C and Ti. After crushing, the granules are sieved so as to obtain a granule size of between 1 and 6 mm. A bulk density of the order of 1.0 g / cm 3 (55% of space between the granules + 40% of porosity in the granules) is obtained. The granules are placed in the part to be reinforced, which thus comprises 45% by volume of porous granules. After reaction, in the reinforced part 45% by volume of zones concentrated to about 45% of globular titanium carbide are obtained, ie 20% by global volume of TiC in the reinforced part of the grinding cone.

Exemple 4Example 4

Dans cet exemple, on a cherché à atténuer l'intensité de la réaction entre le carbone et le titane en y ajoutant un alliage ferreux en poudre. Comme dans l'exemple 2, on vise à réaliser un cône de broyage dont les zones renforcées comportent un pourcentage en volume global de TiC d'environ 30 %. A cette fin, on réalise une bande par compaction à 85 % de la densité théorique d'un mélange en poids de 15 % de C, 63 % de Ti et 22 % de Fe. Après concassage, les granulés sont tamisés de manière à obtenir une dimension de granulés située entre 1.4 et 4 mm. On obtient une densité en vrac de l'ordre de 2 g/cm3 (45 % d'espace entre les granulés + 15 % de porosité dans les granulés). On dispose les granulés dans la partie à renforcer qui comporte ainsi 55 % en volume de granulés poreux. Après réaction, on obtient dans la partie renforcée 55 % en volume de zones avec une forte concentration d'environ 55 % en carbure de titane globulaire, soit 30 % en volume de carbure de titane global dans la macro-microstructure renforcée du cône de broyage.In this example, it was sought to attenuate the intensity of the reaction between carbon and titanium by adding a ferrous alloy powder. As in Example 2, it is intended to provide a grinding cone whose reinforced zones comprise a global volume percentage of TiC of about 30%. For this purpose, a compaction band is produced at 85% of the theoretical density of a mixture by weight of 15% of C, 63% of Ti and 22% of Fe. After crushing, the granules are sieved to obtain a granule size between 1.4 and 4 mm. A bulk density of the order of 2 g / cm 3 (45% of space between the granules + 15% of porosity in the granules) is obtained. The granules are placed in the part to be reinforced, which thus comprises 55% by volume of porous granules. After reaction, 55% by volume of zones with a high concentration of approximately 55% of globular titanium carbide, ie 30% by volume of global titanium carbide in the reinforced macro-microstructure of the grinding cone, are obtained in the reinforced part. .

Les tableaux suivants montrent les nombreuses combinaisons possibles.The following tables show the many possible combinations.

Pourcentage global de TiC obtenu dans la macro-microstructure renforcée après réaction Ti + 0.98 C dans la partie renforcée du cône de broyage Tableau 1 (Ti + 0.98 C) Compaction des granulés (% de la densité théorique qui est de 3,75 g/cm3) 55 60 65 70 75 80 85 90 95 Remplissage de la partie renforcée de la pièce (% vol.) 70 29.3 31.9 34.6 37.2 39.9 42.6 45.2 47.9 50.5 65 27.2 29.6 32.1 34.6 37.1 39.5 42.0 44.5 46.9 55 23.0 25.1 27.2 29.3 31.4 33.4 35.5 37.6 39.7 45 18.8 20.5 22.2 23.9 25.7 27.4 29.1 30.8 32.5 Ce tableau montre qu'avec un niveau de compaction allant de 55 à 95 % pour les bandes et donc les granulés, on peut pratiquer des niveaux de remplissage en granulés dans la partie renforcée du cône de broyage allant de 45 à 70 % en volume (rapport entre le volume total des granulés et le volume de leur confinement). Ainsi, pour obtenir une concentration globale en TiC dans la partie renforcée d'environ 29 % vol. (en lettres grasses dans le tableau), on peut procéder à différentes combinaisons comme par exemple 60 % de compaction et 65 % de remplissage, ou 70 % de compaction et 65 % de remplissage, ou encore 85 % de compaction et 45 % de remplissage. Pour obtenir des niveaux de remplissage en granulés dans la partie renforcée allant jusqu'à 70 % en volume, on est obligé d'appliquer une vibration pour tasser les granulés. Dans ce cas, la norme ISO 697 pour la mesure du taux de remplissage n'est plus applicable et on mesure la quantité de matière dans un volume donné.Overall percentage of TiC obtained in the reinforced macro-microstructure after Ti + 0.98 C reaction in the reinforced part of the grinding cone <b> Table 1 (Ti + 0.98 C) </ b> Compaction of the granules (% of the theoretical density which is 3.75 g / cm 3 ) 55 60 65 70 75 80 85 90 95 Filling the reinforced part of the part (% vol.) 70 29.3 31.9 34.6 37.2 39.9 42.6 45.2 47.9 50.5 65 27.2 29.6 32.1 34.6 37.1 39.5 42.0 44.5 46.9 55 23.0 25.1 27.2 29.3 31.4 33.4 35.5 37.6 39.7 45 18.8 20.5 22.2 23.9 25.7 27.4 29.1 30.8 32.5 This table shows that with a compaction level ranging from 55 to 95% for the strips and therefore the granules, it is possible to practice filling levels in granules in the reinforced part of the grinding cone ranging from 45 to 70% by volume ( ratio between the total volume of pellets and the volume of their confinement). Thus, to obtain an overall concentration of TiC in the reinforced portion of about 29% vol. (in bold letters in the table), one can proceed to different combinations such as for example 60% of compaction and 65% of filling, or 70% of compaction and 65% of filling, or else 85% of compaction and 45% of filling . To obtain granular filling levels in the reinforced portion up to 70% by volume, it is necessary to apply a vibration to compact the granules. In this case, the ISO 697 standard for measuring the degree of filling is no longer applicable and the quantity of material in a given volume is measured.

Relation entre le niveau de compaction, la densité théorique et le pourcentage de TiC obtenu après réaction dans le granulé Tableau 2 Compaction des granulés 55 60 65 70 75 80 85 90 95 Densité en g/cm3 2.06 2.25 2.44 2.63 2.81 3.00 3.19 3.38 3.56 TiC obtenu après réaction (et contraction) en % vol. dans les granulés 41.8 45.6 49.4 53.2 57.0 60.8 64.6 68.4 72.2 Ici nous avons représenté la densité des granulés en fonction de leur niveau de compaction et on en a déduit le pourcentage volumique de TiC obtenu après réaction et donc contraction d'environ 24 % vol. Des granulés compactés à 95 % de leur densité théorique permettent donc d'obtenir après réaction, une concentration de 72.2 % vol. en TiC.Relationship between the compaction level, the theoretical density and the percentage of TiC obtained after reaction in the granule <b><u> Table 2 </ u></b> Compaction of granules 55 60 65 70 75 80 85 90 95 Density in g / cm 3 2.06 2.25 2.44 2.63 2.81 3.00 3.19 3.38 3.56 TiC obtained after reaction (and contraction) in% vol. in the granules 41.8 45.6 49.4 53.2 57.0 60.8 64.6 68.4 72.2 Here we have represented the density of the granules as a function of their level of compaction and deduced the volume percentage of TiC obtained after reaction and thus contraction of about 24% vol. Granules compacted to 95% of their theoretical density thus make it possible to obtain after reaction a concentration of 72.2% vol. in TiC.

Densité en vrac de l'empilement des granulés Tableau 3 Compaction 55 60 65 70 75 80 85 90 95 Remplissage de la partie renforcée de la pièce en % vol 70 1.4 1.6 1.7 1.8 2 2.1 2.2 2.4 2.5 65 1.3* 1.5 1.6 1.7 1.8 2.0 2.1 2.2 2.3 55 1.1 1.2 1.3 1.4 1.5 1.7 1.8 1.9 2.0 45 0.9 1.0 1.1 1.2 1.3 1.4 1.4 1.5 1.6 (*) Densité en vrac (1.3) = densité théorique (3.75 g/cm3) x 0.65 (remplissage) x 0.55 (compaction) En pratique, ces tableaux servent d'abaques à l'utilisateur de cette technologie, qui se fixe un pourcentage global de TiC à réaliser dans la partie renforcée du cône de broyage et qui en fonction de cela détermine le niveau de remplissage et la compaction des granulés qu'il va utiliser. Les mêmes tableaux ont été réalisés pour un mélange de poudres Ti + C + Fe.Bulk density of the stack of pellets <b><u> Table 3 </ u></b> compaction 55 60 65 70 75 80 85 90 95 Filling the reinforced part of the part in% vol 70 1.4 1.6 1.7 1.8 2 2.1 2.2 2.4 2.5 65 1.3 * 1.5 1.6 1.7 1.8 2.0 2.1 2.2 2.3 55 1.1 1.2 1.3 1.4 1.5 1.7 1.8 1.9 2.0 45 0.9 1.0 1.1 1.2 1.3 1.4 1.4 1.5 1.6 (*) Bulk density (1.3) = theoretical density (3.75 g / cm 3 ) x 0.65 (filling) x 0.55 (compaction) In practice, these tables are used by the user of this technology, which sets a global percentage of TiC to be produced in the reinforced part of the grinding cone and which, as a result, determines the level of filling and the compaction of the elements. granules that he will use. The same tables were made for a mixture of Ti + C + Fe powders.

Ti + 0.98 C + FeTi + 0.98 C + Fe

Ici, l'inventeur a visé un mélange permettant d'obtenir 15% en volume de fer après réaction. La proportion de mélange qui a été utilisée est de :
100g Ti + 24.5g C + 35.2g Fe

  • Nous entendons par poudre de fer : fer pur ou alliage de fer.
  • Densité théorique du mélange : 4.25g/cm3
  • Retrait volumétrique lors de la réaction : 21 %
Here, the inventor has targeted a mixture to obtain 15% by volume of iron after reaction. The proportion of mixture that has been used is:
100g Ti + 24.5g C + 35.2g Fe
  • We mean by iron powder: pure iron or iron alloy.
  • Theoretical density of the mixture: 4.25g / cm 3
  • Volumetric shrinkage during the reaction: 21%

Pourcentage global de TiC obtenu dans la macro-microstructure renforcée après réaction Ti + 0.98 C + Fe dans la partie renforcée du cône de broyage Tableau 4 Compaction des granulés (% de la densité théorique qui est de 4.25 g/cm3) 55 60 65 70 75 80 85 90 95 Remplissage de la partie renforcée de la pièce (% vol) 70 25.9 28.2 30.6 32.9 35.5 37.6 40.0 42.3 44.7 65 24.0 26.2 28.4 30.6 32.7 34.9 37.1 39.3 41.5 55 20.3 22.2 24.0 25.9 27.7 29.5 31.4 33.2 35.1 45 16.6 18.1 19.6 21.2 22.7 24.2 25.7 27.2. 28.7 A nouveau, pour obtenir une concentration globale en TiC dans la partie renforcée d'environ 26 % vol (en lettres grasses dans le tableau), on peut procéder à différentes combinaisons comme par exemple 55 % de compaction et 70 % de remplissage, ou 60 % de compaction et 65 % de remplissage, ou 70 % de compaction et 55 % de remplissage, ou encore 85 % de compaction et 45 % de remplissage.Overall percentage of TiC obtained in the reinforced macro-microstructure after reaction Ti + 0.98 C + Fe in the reinforced part of the grinding cone <b><u> Table 4 </ u></b> Compaction of the granules (% of theoretical density which is 4.25 g / cm 3 ) 55 60 65 70 75 80 85 90 95 Filling the reinforced part of the part (% vol) 70 25.9 28.2 30.6 32.9 35.5 37.6 40.0 42.3 44.7 65 24.0 26.2 28.4 30.6 32.7 34.9 37.1 39.3 41.5 55 20.3 22.2 24.0 25.9 27.7 29.5 31.4 33.2 35.1 45 16.6 18.1 19.6 21.2 22.7 24.2 25.7 27.2. 28.7 Again, to obtain an overall concentration of TiC in the reinforced part of about 26% vol (in bold letters in the table), one can proceed to different combinations such as for example 55% compaction and 70% filling, or 60%. % compaction and 65% filling, or 70% compaction and 55% filling, or 85% compaction and 45% filling.

Relation entre le niveau de compaction, la densité théorique et le pourcentage de TiC, obtenue après réaction dans le granulé en tenant compte de la présence de fer Tableau 5 Compaction des granulés 55 60 65 70 75 80 85 90 95 Densité en g/cm3 2.34 2.55 2.76 2.98 3.19 3.40 3.61 3.83 4.04 TiC obtenu après réaction (et contraction) en %vol. dans les granulés 36.9 40.3 43.6 47.0 50.4 53.7 57.1 60.4 63.8 Relationship between the compaction level, the theoretical density and the percentage of TiC, obtained after reaction in the granule taking into account the presence of iron <b><u> Table 5 </ u></b> Compaction of granules 55 60 65 70 75 80 85 90 95 Density in g / cm 3 2.34 2.55 2.76 2.98 3.19 3.40 3.61 3.83 4.04 TiC obtained after reaction (and contraction) in% vol. in the granules 36.9 40.3 43.6 47.0 50.4 53.7 57.1 60.4 63.8

Densité en vrac de l'empilement des granulés (Ti + C + Fe) Tableau 6 Compaction 55 60 65 70 75 80 85 90 95 Remplissage de la partie renforcée de la pièce en % vol. 70 1.6 1.8 1.9 2.1 2.2 2.4 2.5 2.7 2.8 65 1.5* 1.7 1.8 1.9 2.1 2.2 2.3 2.5 2.6 55 1.3 1.4 1.5 1.6 1.8 1.9 2.0 2.1 2.2 45 1.1 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 (*) Densité en vrac (1.5) = densité théorique (4.25) x 0.65 (remplissage) x 0.55 (compaction) Bulk density of the stack of pellets (Ti + C + Fe) <b><u> Table 6 </ u></b> compaction 55 60 65 70 75 80 85 90 95 Filling the reinforced part of the piece in% vol. 70 1.6 1.8 1.9 2.1 2.2 2.4 2.5 2.7 2.8 65 1.5 * 1.7 1.8 1.9 2.1 2.2 2.3 2.5 2.6 55 1.3 1.4 1.5 1.6 1.8 1.9 2.0 2.1 2.2 45 1.1 1.1 1.2 1.3 1.4 1.5 1.6 1.7 1.8 (*) Bulk density (1.5) = theoretical density (4.25) x 0.65 (filling) x 0.55 (compaction)

AvantagesAdvantages

La présente invention présente les avantages suivants par rapport à l'état de la technique en général:The present invention has the following advantages over the state of the art in general:

Meilleure résistance aux chocsBetter shock resistance

Avec le présent procédé, on a des granulés millimétriques poreux qui sont sertis dans l'alliage métallique d'infiltration. Ces granulés millimétriques sont eux-mêmes composés de particules microscopiques de TiC à tendance globulaire également sertis dans l'alliage métallique d'infiltration. Ce système permet d'obtenir un cône de broyage avec une zone de renfort comportant une macrostructure au sein de laquelle il y a une microstructure identique à une échelle environ mille fois plus petite.With the present process, there are porous millimetric granules which are crimped into the metal infiltration alloy. These millimetric granules are themselves composed of microscopic particles of globular TiC also crimped in the metal alloy infiltration. This system makes it possible to obtain a grinding cone with a reinforcing zone comprising a macrostructure within which there is an identical microstructure on a scale approximately a thousand times smaller.

Le fait que la zone de renfort du cône de broyage comporte des petites particules globulaires de carbure de titane, dures et finement dispersées dans une matrice métallique qui les entoure, permet d'éviter la formation et la propagation des fissures (voir Fig. 4 & 6). On a ainsi un double système dissipatif des fissures.The fact that the reinforcing zone of the grinding cone comprises small globular particles of titanium carbide, hard and finely dispersed in a metal matrix around them, avoids the formation and propagation of cracks (see Fig. 4 & 6 ). There is thus a double dissipative system of cracks.

Les fissures prennent généralement naissance aux endroits les plus fragiles, qui sont dans ce cas la particule de TiC ou l'interface entre cette particule et l'alliage métallique d'infiltration. Si une fissure prend naissance à l'interface ou dans la particule micrométrique de TiC, la propagation de cette fissure est ensuite entravée par l'alliage d'infiltration qui entoure cette particule. La ténacité de l'alliage d'infiltration est supérieure à celle de la particule céramique TiC. La fissure a besoin de plus d'énergie pour passer d'une particule à l'autre, pour franchir les espaces micrométriques qui existent entre les particules.Cracks generally originate at the most fragile places, which in this case are the TiC particle or the interface between this particle and the infiltration metal alloy. If a crack originates at the interface or in the micrometric particle of TiC, the propagation of this crack is then impeded by the infiltration alloy which surrounds this particle. The toughness of the infiltration alloy is greater than that of the TiC ceramic particle. The crack needs more energy to pass from one particle to another, to cross the micrometric spaces that exist between the particles.

Flexibilité maximale pour les paramètres de mise en oeuvreMaximum flexibility for implementation parameters

Outre le niveau de compaction des granulés, on peut faire varier deux paramètres qui sont la fraction granulométrique et la forme des granulés, et donc leur densité en vrac. Par contre, dans une technique de renforcement par insert, on ne peut faire varier que le niveau de compaction de celui-ci dans une plage limitée. Au niveau de la forme que l'on souhaite donner au renforcement, compte tenu du design du cône de broyage et de l'endroit que l'on souhaite renforcer, l'utilisation de granulés permet davantage de possibilités et d'adaptation. (voir figure 3)In addition to the level of compaction of the granules, it is possible to vary two parameters which are the granulometric fraction and the shape of the granules, and therefore their bulk density. On the other hand, in an insert reinforcement technique, it is only possible to vary the level of compaction thereof in a limited range. In terms of the shape that we want to give the reinforcement, given the design of the grinding cone and the place that we want to strengthen, the use of granules allows more opportunities and adaptation. (see figure 3 )

Avantages au niveau de la fabricationAdvantages in manufacturing

L'utilisation comme renforcement d'un empilement de granulés poreux, présente certains avantages au niveau de la fabrication :

  • moins de dégagement gazeux,
  • moindre susceptibilité à la crique,
  • meilleure localisation du renforcement dans le cône de broyage.
La réaction entre le Ti et le C est fortement exothermique. L'élévation de température provoque un dégazage des réactifs, c'est-à-dire des matières volatiles comprises dans les réactifs (H2O dans le carbone, H2, N2 dans le titane). Au plus la température de réaction est élevée, au plus ce dégagement est important. La technique par granulés permet de limiter la température, de limiter le volume gazeux et permet une évacuation plus facile des gaz et ainsi de limiter les défauts de gaz. (voir Fig. 9 avec bulle de gaz indésirable).The use as reinforcement of a stack of porous granules, has certain advantages at the level of manufacture:
  • less gassing,
  • less susceptibility to the crack,
  • better localization of the reinforcement in the grinding cone.
The reaction between Ti and C is strongly exothermic. The rise in temperature causes degassing of the reagents, that is to say volatile materials included in the reagents (H 2 O in carbon, H 2 , N 2 in titanium). The higher the reaction temperature, the greater this clearance is important. The granular technique makes it possible to limit the temperature, to limit the gaseous volume and allows an easier evacuation of the gases and thus to limit the gas defects. (see Fig. 9 with unwanted gas bubble).

Faible susceptibllité à la crique lors de la fabrication du cône de broyage selon l'inventionLow susceptibility to crack during the manufacture of the grinding cone according to the invention

Le coefficient de dilatation du renforcement TiC est plus faible que celui de la matrice en alliage ferreux (coefficient de dilatation du TiC : 7.5 10-6 /K et de l'alliage ferreux : environ 12.0 10-6/K). Cette différence dans les coefficients de dilatation a pour conséquence de générer des tensions dans le matériau pendant la phase de solidification et aussi lors du traitement thermique. Si ces tensions sont trop importantes, des criques peuvent apparaître dans la pièce et conduire au rebut de celle-ci. Dans la présente invention, on utilise une faible proportion de renforcement TiC (moins de 50 % en volume), ce qui entraîne moins de tensions dans la pièce. De plus, la présence d'une matrice plus ductile entre les particules globulaires micrométriques de TiC en zones alternées de faible et de forte concentration permet de mieux gérer d'éventuelles tensions locales.The expansion coefficient of the TiC reinforcement is lower than that of the ferrous alloy matrix (TiC expansion coefficient: 7.5 × 10 -6 / K and the ferrous alloy: about 12.0 × 10 -6 / K). This difference in the expansion coefficients has the consequence of generating tensions in the material during the solidification phase and also during the heat treatment. If these voltages are too great, cracks may appear in the room and lead to scrapping it. In the present invention, a small proportion of TiC reinforcement (less than 50% by volume) is used, resulting in less stress in the part. In addition, the presence of a more ductile matrix between the micrometric globular particles of TiC in alternating zones of low and high concentration makes it possible to better manage any local voltages.

Excellent maintien du renforcement dans le cône de broyageExcellent retention of reinforcement in the grinding cone

Dans la présente invention, la frontière entre la partie renforcée et la partie non renforcée du cône de broyage n'est pas abrupte puisqu'il y a une continuité de la matrice métallique entre la partie renforcée et la partie non renforcée, ce qui permet de la protéger contre un arrachage complet du renforcement.In the present invention, the boundary between the reinforced portion and the unreinforced portion of the grinding cone is not abrupt because there is a continuity of the metal matrix between the reinforced portion and the unreinforced portion, thereby protect it against a complete tearing of the reinforcement.

Résultats de testsTest results

Trois tests ont été effectués avec des cônes du type de celui représenté à la figure 3.

  • Test 1
    concasseur secondaire
    matériau concassé : agrégats, abrasivité élevée
    augmentation de la durée de vie du cône renforcé par rapport à un cône en acier au manganèse : 50%
  • Test 2
    concasseur secondaire
    matériau concassé : agrégats, abrasivité moyenne
    augmentation de la durée de vie du cône renforcé par rapport à un cône en acier au manganèse : 130%
  • Test 3
    concasseur secondaire
    matériau concassé : agrégats, abrasivité moyenne
    augmentation de la durée de vie du cône renforcé par rapport à un cône en acier au manganèse : 170%
Three tests were carried out with cones of the type represented in figure 3 .
  • Test 1
    secondary crusher
    Crushed material: aggregates, high abrasiveness
    increase in the life of the reinforced cone compared to a manganese steel cone: 50%
  • Test 2
    secondary crusher
    crushed material: aggregates, medium abrasiveness
    increase in the life of the reinforced cone compared to a manganese steel cone: 130%
  • Test 3
    secondary crusher
    crushed material: aggregates, medium abrasiveness
    increase in the life of the reinforced cone compared to a manganese steel cone: 170%

Claims (13)

  1. A composite milling cone for compression crushers, said milling cone comprising a ferrous alloy at least partially reinforced (5) with titanium carbide according to a defined geometry, wherein said reinforced portion (5) comprises an alternating macro-microstructure of millimetric areas (1) concentrated with micrometric globular particles of titanium carbide (4) separated by millimetric areas (2) essentially free of micrometric globular particles of titanium carbide (4), said areas concentrated with micrometric globular particles of titanium carbide (4) forming a microstructure in which the micrometric interstices (3) between said globular particles (4) are also filled by said ferrous alloy.
  2. The milling cone according to claim 1, wherein said millimetric concentrated areas have a concentration of micrometric globular particles of titanium carbide (4) greater than 36.9% by volume.
  3. The milling cone according to any of claims 1 or 2, wherein said reinforced portion has a global titanium carbide content between 16.6 and 50.5% by volume.
  4. The milling cone according to any of the preceding claims, wherein the micrometric globular particles of titanium carbide (4) have a size of less than 50µm.
  5. The milling cone according to any of the preceding claims, wherein the major portion of the micrometric globular particles of titanium carbide (4) has a size of less than 20 µm.
  6. The milling cone according to any of the preceding claims, wherein said areas concentrated with globular particles of titanium carbide (1) comprise 36.9 to 72.2% by volume of titanium carbide.
  7. The milling cone according to any of the preceding claims, wherein said areas concentrated with titanium carbide (1) have a dimension varying from 1 to 12 mm.
  8. The milling cone according to any of the preceding claims, wherein said areas concentrated in titanium carbide (1) have a dimension varying from 1 to 6 mm.
  9. The milling cone according to any of the preceding claims, wherein said areas concentrated in titanium carbide (1) have a dimension varying from 1.4 to 4 mm.
  10. A method for manufacturing by casting a composite milling cone according to any of claims 1 to 9, comprising the following steps:
    - providing a mold comprising the imprint of the milling cone with a predefined reinforcement geometry;
    - introducing, into the portion of the imprint of the milling cone intended to form the reinforced portion (5), a mixture of compacted powders comprising carbon and titanium in the form of millimetric granules precursor of titanium carbide;
    - casting a ferrous alloy into the mold, the heat of said casting triggering an exothermic self-propagating high temperature synthesis (SHS) of titanium carbide within said precursor granules;
    - forming, within the reinforced portion (5) of the milling cone, an alternating macro-microstructure of millimetric areas concentrated (1) with micrometric globular particles of titanium carbide (4) at the location of said precursor granules, said areas being separated from each other by millimetric areas (2) essentially free of micrometric globular particles of titanium carbide (4), said globular particles (4) being also separated within said millimetric areas concentrated (1) with titanium carbide by micrometric interstices (3);
    - infiltration of the millimetric (2) and micrometric (3) interstices by said high temperature cast ferrous alloy, following the formation of microscopic globular particles of titanium carbide (4).
  11. The manufacturing method according to claim 10, wherein the mixture of compacted powders of titanium and carbon comprises a powder of a ferrous alloy.
  12. The manufacturing method according to any of claims 10 or 11, wherein said carbon is graphite.
  13. The milling cone obtained according to any of claims 10 to 12.
EP09782200.1A 2008-09-19 2009-08-26 Milling cone for a compression crusher Active EP2326738B9 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
PL09782200T PL2326738T3 (en) 2008-09-19 2009-08-26 Milling cone for a compression crusher

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
BE2008/0519A BE1018128A3 (en) 2008-09-19 2008-09-19 GRINDING CONE FOR COMPRESSION CRUSHER.
PCT/EP2009/060979 WO2010031661A1 (en) 2008-09-19 2009-08-26 Milling cone for a compression crusher

Publications (3)

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EP2326738A1 EP2326738A1 (en) 2011-06-01
EP2326738B1 EP2326738B1 (en) 2012-03-21
EP2326738B9 true EP2326738B9 (en) 2013-06-19

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EP (1) EP2326738B9 (en)
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CL (1) CL2011000575A1 (en)
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WO2017081665A1 (en) 2015-11-12 2017-05-18 Innerco Sp. Z O.O. Powder composition for the manufacture of casting inserts, casting insert and method of obtaining local composite zones in castings
CN110020481B (en) * 2019-04-10 2023-05-02 江西理工大学 Multi-gradient structure enhanced cone crusher lining plate and design method thereof
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BE1027444B1 (en) 2020-02-11 2021-02-10 Magotteaux Int COMPOSITE WEAR PART
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ES2384089T3 (en) 2012-06-29
ZA201101790B (en) 2012-08-29
MY150574A (en) 2014-01-30
ES2384089T9 (en) 2013-09-16
EP2326738A1 (en) 2011-06-01
DK2326738T3 (en) 2012-07-16
EP2326738B1 (en) 2012-03-21
PT2326738E (en) 2012-06-28
PL2326738T3 (en) 2012-08-31
CN102159739B (en) 2013-02-06
US20110303778A1 (en) 2011-12-15
CA2743744C (en) 2015-10-06
CA2743744A1 (en) 2010-03-25
CL2011000575A1 (en) 2011-08-26
BRPI0913557B1 (en) 2019-12-24
US8602340B2 (en) 2013-12-10
AU2009294780A1 (en) 2010-03-25
AU2009294780B2 (en) 2013-04-18
BRPI0913557A2 (en) 2015-10-20
BE1018128A3 (en) 2010-05-04
MX2011003027A (en) 2011-04-12
CN102159739A (en) 2011-08-17
WO2010031661A1 (en) 2010-03-25
ATE550450T1 (en) 2012-04-15

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