EP1598114A1 - Method of separating silica and olivine from a mixture containing these substances and device for carrying out said method - Google Patents

Abstract

Process for separating silica (I) and olivine (II) from a mixture comprises at least one magnetic separation step and at least one heat-treatment step to produce a mixture (9) regenerated in (I) and a mixture (11) regenerated in (II). An independent claim is also included for a device for the process comprising magnetic separators and a heat-treatment enclosure.

Description

The present invention relates to a method of separation of silica and olivine in a mixture of container.

The present invention also relates to a device for implementing this method.

More particularly, the invention relates to a recycling process of a mixture containing silica and olivine from the manufacture of parts metal molding.

During such manufacture of metal parts, particles or a mixture of particles, often mixed with hardeners such as resins, are used to form the temporary rigid structure serving as a mold and intended to receive the metal fusion.

When the metal is cooled and hardened, the piece obtained is extracted from the mold by a stall consisting of separating the particles from the room metal obtained.

Of the particles usually used, the silica has many advantages. Indeed, this guy sand has an abundance of significant deposits, its extraction is easy, its refractoriness is sufficient since its melting temperature is close to 1700 ° C and its cost price is low.

Nevertheless, the silica can react chemically and / or thermally with certain metals at the level of the interface with the metal used which limits its use.

For example, when manufacturing parts in manganese steel, the contact between silica and this type steel is outlawed because of the formation of a eutectic with a low melting point watering and / or vitrification.

The use of other types of particles in Steel contact is then necessary.

For this purpose, it is well known that chromite and olivine can be used as sand on contact of steel, called sand of contact, the sand allowing fill the rest of the mold, called sand filling, which may be silica.

For the manufacture of this type of metal parts, the use of olivine as contact sand has certain advantages since its cost is lower than that of chromite, olivine does not have any constraints on the rejects contrary to chromite which can lead to the formation of Cr ^VI , and the fineness of the grain of olivine makes it possible to manufacture parts with properties of improved surfaces.

When using a mixture of olivine, as contact sand, and silica, as sand of filling, the shake operation leads to get a mixture of silica and olivine which can not be used as than such to be reused in contact sand.

Unlike chromite, for which know a separation process with silica by a simple magnetic sorting operation, no method of separation of silica and olivine to obtain less recyclable olivine has so far been brought to the knowledge of the applicant.

The object of the invention is therefore mainly to separation process of olivine and silica into a mixture containing it for the purpose of recycling.

(a) une étape de tri magnétique 2,8; et

(b) une étape de traitement thermique 6,

   desquelles il résulte notamment un mélange régénéré en olivine 9 et un mélange régénéré en silice 11.For this purpose, the method of the invention mainly comprises the following steps:

(a) a magnetic sorting step 2,8; and

(b) a heat treatment step 6,

from which results in particular a regenerated mixture of olivine 9 and a regenerated mixture silica 11.

(a) une première étape de tri magnétique 2 dudit mélange 1 de laquelle il résulte notamment un premier mélange rééquilibré en olivine et en silice 4 et un mélange enrichi en silice 3;

(b) une étape de traitement thermique 6 du premier mélange régénéré en olivine 4 issu de l'étape (a) ; et

(c) une deuxième étape de tri magnétique 8 du mélange 7 issu de l'étape (b) de laquelle il résulte notamment un mélange régénéré en olivine 9 et un mélange régénéré en silice 11.

Advantageously, the method of the invention comprises the following steps:

(a) a first step of magnetic sorting 2 of said mixture 1 which results in particular a first equilibrium mixture of olivine and silica 4 and a mixture enriched in silica 3;

(b) a heat treatment step 6 of the first regenerated olivine mixture 4 from step (a); and

(c) a second step of magnetic sorting 8 of the mixture 7 resulting from step (b), which results in particular from a regenerated mixture of olivine 9 and a regenerated mixture of silica 11.

(a)la première étape de tri magnétique 2;

(b)l'étape de traitement thermique 6 du mélange rééquilibré en olivine et en silice 4 obtenu à l'étape (a) ; et

(c)la deuxième étape de tri magnétique 8 du mélange 7 obtenu à l'étape (b).

Preferably, the method comprises, in the order, the following steps:

(a) the first magnetic sorting step 2;

(b) the heat treatment step 6 of the equilibrium mixture of olivine and silica 4 obtained in step (a); and

(c) the second magnetic sorting step 8 of the mixture 7 obtained in step (b).

According to the invention, the mixture containing silica and olivine 1 may be derived from the operation of stalling performed during the manufacture of parts metal molding and contains between 5 and 40% olivine, silica and particles strongly magnetic such as iron oxide particles.

(a1) une première étape de séparation magnétique 14 pour isoler des particules fortement magnétiques 5 du mélange contenant de l'olivine et de la silice 1; et

(a2) une seconde étape de séparation magnétique 15 du mélange appauvri en particules fortement magnétiques 19 obtenu à l'étape (a1) pour éliminer les particules fortement magnétiques résiduelles 5 et obtenir :

• le mélange enrichi en silice 3, et
• le mélange rééquilibré en silice et en olivine 4.

Preferably, the first magnetic sorting step 2 of the process of the invention comprises at least the following steps:

(a1) a first magnetic separation step 14 for isolating highly magnetic particles from the mixture containing olivine and silica 1; and

(a2) a second step of magnetically separating the strongly magnetic particle depleted mixture 19 obtained in step (a1) to remove residual high magnetic particles and obtain:

• the mixture enriched with silica 3, and
• the rebalanced mixture of silica and olivine 4.

According to the invention, the mixture enriched with silica 3 can be used as filling sand.

Also according to the invention, the rebalanced mixture olivine and silica 4 contains approximately 50% silica and 50% olivine.

Preferably, the treatment step 6 of the process of the invention consists of subject the rebalanced mixture to olivine and silica 4 at a temperature above 400 ° C.

Advantageously, the heat treatment step 6 consists in treating the rebalanced mixture with olivine and in silica 4 in a fluidized bed furnace 25 to a temperature of approximately 650 ° C.

It is also advantageous that the mixture rebalanced to olivine and silica 4 be cooled to a temperature of less than 50 ° C.

(c1) une première étape de séparation magnétique 34 pour séparer les particules fortement magnétiques 12 du mélange 7 issu de l'étape de traitement thermique 6; et

(c2) une deuxième étape de séparation magnétique 35 du mélange appauvri en particules fortement magnétiques 39 obtenu à l'étape (c1) pour éliminer les particules fortement magnétiques résiduelles 12 et obtenir :

• le mélange régénéré en silice 11,
• le mélange régénéré en olivine 9, et
• le mélange d'olivine et de silice 10.

According to the invention, the second magnetic sorting step 8 advantageously comprises at least the following steps:

(c1) a first magnetic separation step 34 for separating the strongly magnetic particles 12 from the mixture 7 resulting from the heat treatment step 6; and

(c2) a second step of magnetic separation of the strongly magnetic particulate depleted mixture obtained in step (c1) to remove the residual strongly magnetic particles 12 and obtain:

• the regenerated mixture of silica 11,
• the regenerated mixture of olivine 9, and
• the mixture of olivine and silica 10.

Advantageously, the regenerated mixture of silica 11 can be used as hanging sand and mixing regenerated to olivine 9 contains more than 90% olivine and can be used as contact sand.

According to the invention, the mixture of silica and olivine obtained in step (c2) can undergo again the second step of magnetic sorting 8.

• une machine de tri magnétique 13, 33, et
• une enceinte de traitement thermique 25.

The invention also relates to a device for separating silica from olivine in a mixture 1 containing thereof which comprises at least:

• a magnetic sorting machine 13, 33, and
• a heat treatment chamber 25.

• une première machine de tri magnétique 13,
• une enceinte de traitement thermique 26, et
• une deuxième machine de tri magnétique 33.

Preferably, the device of the invention comprises at least:

• a first magnetic sorting machine 13,
• a heat treatment chamber 26, and
• a second magnetic sorting machine 33.

Advantageously, the first sorting machine magnetic 13, the heat treatment chamber 25 and the second sorting machine 33 are arranged in this order and in series.

In addition, the first magnetic sorting machine 13 may comprise a first magnetic separator 16 set to separate the strongly magnetic particles 12 from mixture containing olivine and silica 1 and a second magnetic separator 21 to separate, from mixture depleted in strongly magnetic particles 12, the strongly magnetic residual particles 12 and obtain a mixture enriched with silica 3 and a mixture rebalanced to olivine and silica 4.

Preferably, the first 16 and second 21 Magnetic separators are constituted by first 16 and second 21 magnetized metal drums in rotation on which the mixture to be separated 1, 19 circulates at an appropriate speed and by one or more shutters adjustable inclination 20, 23, 24 arranged downstream of the drums 16,21 so as to separate the different jets from sand thrown by drums 16,21 and corresponding respectively to strongly magnetic particles 5, mixture enriched with silica 3 and the rebalanced mixture olivine and silica 4.

More specifically, a flap 20 can be arranged in downstream of the first magnetic drum 16 so as to separate of the mixture containing olivine and silica 1 strongly magnetic particles 5.

With regard to the second drum 21, two shutters can be arranged downstream of the second drum 21 so as to separate selectively, from the mixture depleted in strongly magnetic particles 19, the strongly magnetic residual particles 5, the mixture enriched in silica 3, and the mixture rebalanced in olivine and silica 4.

Advantageously, the treatment chamber thermal 25 is constituted by a fluidized bed furnace wherein the rebalanced mixture of olivine and silica 4 progresses in the furnace by fluidization to a temperature of about 650 ° C.

Preferably, a cooler 32 is disposed in downstream of the oven and allows to bring the rebalanced mixture in olivine and silica 4 at a lower temperature at 50 ° C.

According to the invention, the second sorting machine magnetic 33 may comprise a first separator magnetic 36 set to separate the particles strongly 12 of the mixture resulting from the heat treatment 7 and a second magnetic separator 41 set to separate, from this mixture depleted in particles strongly magnetic 39, strongly magnetic particles residuals 12, the regenerated mixture of silica 11, the regenerated mixture of olivine 9 and a mixture of olivine and of silica 10.

Preferably, the first and second separators 36,41 are first 36 and second 41 metal drums magnetized in rotation on which mixture to be separated 7.39 circulates at a speed appropriate and by one or more tilt flaps adjustable 40, 43, 44, 45 arranged downstream of the drums 36,41 so as to separate the different jets of sand projected by drums 36,41 and corresponding respectively to strongly magnetic particles 12, to the regenerated mixture of silica 11, to the regenerated mixture olivine 9 and the mixture of olivine and silica 10.

With regard to the first drum 36, a flap 40 may be disposed downstream of this first drum magnet 36 being adjusted to separate, from mixture resulting from the heat treatment 7 circulating on the first drum, strongly magnetic particles 12.

With regard to the second drum 41, three flaps 43, 44, 45 may be disposed downstream thereof second drum 41 being adjusted to separate selectively from the particulate depleted mixture magnetic devices 39 traveling on the second drum 41, the strongly magnetic residual particles 12, the regenerated mixture of silica 11, the regenerated mixture olivine 9 and the mixture of olivine and silica 10.

In addition, the device of the invention can include means for the mixture of olivine and silica 10 be introduced back into the second magnetic sorting machine 33.

• la figure 1 est un organigramme illustrant les principales étapes du procédé de l'invention,
• la figure 2 représente schématiquement les principaux constituants de la première machine de tri,
• la figure 3 représente schématiquement le four à lit fluidisé utilisé pour le traitement thermique, et
• la figure 4 représente schématiquement les principaux constituants de la deuxième machine de tri.

The invention will be better understood and other objects, advantages and characteristics thereof will appear more clearly on reading the description which follows and which is made with reference to the accompanying drawings which show non-limiting examples of embodiment of the method and of the device of the invention and in which:

• FIG. 1 is a flowchart illustrating the main steps of the method of the invention,
• FIG. 2 diagrammatically represents the main constituents of the first sorting machine,
• FIG. 3 schematically represents the fluidized bed furnace used for the heat treatment, and
• Figure 4 shows schematically the main components of the second sorting machine.

After the stall operation performed at a temperature below 200 ° C, the sand, consisting of a mixture of about 85% silica, 15% olivine and iron oxide particles and metal particles from the casting in small quantities, is screened and sieved to remove scrap or pieces of agglomerated sand.

After dedusting and cooling, the sand is sent by pneumatic transport to a silo buffer.

With reference to Figure 1, the sand from the shake operation 1 undergoes a first step of magnetic sort 2 at the end of which are separated a mixture regenerated enriched silica 3 containing about 85% of silica that is used as filling sand for the manufacture of a metal part, a mixture rebalanced to olivine and silica 4 containing about 50% olivine and 50% silica intended to undergo the stage subsequent heat treatment and particles strongly magnetic 5 which are eliminated from the circuit.

In quantitative terms, the mixture enriched in silica represents about 60% rebalanced the mass of sand 1, the regenerated mixture of olivine and silica represents about 30% of the mass of sand 1 and the strongly magnetic particles about 10%.

Rebalanced mixture of olivine and silica 4 then undergoes a heat treatment step 6 at a temperature of about 650 ° C followed by cooling to a temperature below 50 ° C.

This heat treatment step 6 allows in particular to obtain a physical dissociation of the grains of silica and olivine which may have agglomerated the presence of the chemical components used during the molding operation such as resins for example.

The rebalanced mixture of olivine and silica 7 obtained at the end of the heat treatment step 6 then undergoes a second step of magnetic sorting 8 to the outcome of which is separated a regenerated mixture silica 11 containing more than 70% silica that is directed to a storage silo for reuse as hanging sand, a regenerated mixture of olivine 9 containing more than 90% olivine and which may be reused as contact sand during manufacture of a new metal part, particles strongly magnetic 12 which are eliminated from the circuit and a mixture of olivine and silica 10 which undergoes the second step of magnetic sorting 8.

In quantitative terms, the regenerated mixture silica represents about 10% by weight of the mass of sand 1, the regenerated mixture of olivine represents about 15% by weight of the mass of sand 1, the strongly magnetic particles about 0.5% and the mixture of olivine and silica about 8.5%.

With reference to FIG. 2, the shakeout sand 1 undergone, during the first stage of magnetic sorting 2 put implemented by the first magnetic sorting machine 13, a first step of magnetic separation 14 followed a second magnetic separation step 15.

The first step of magnetic separation 14 is to recover some of the particles strongly magnetic materials such as iron oxide particles and metal particles from the casting finding in the shaking sand 1 in order to facilitate the second magnetic separation step 15.

For this, a first separation machine magnet 16 is constituted by a first drum in rotation 16 having a metal casing to inside which magnets are arranged permanent rare earths.

The shaking sand 1 is brought to the first rotating drum 16 by a vibrating mat 17 surmounted a squeegee adjustable in height 18 allowing to spread the sand evenly over the carpet 17.

The sand 1 is then driven by the drum 16 and the different components of sand 1 are, under the combined influence of their magnetic properties respective centrifugal force from the drum 16 in rotation and the effect of gravity, projected downstream drum in the form of sand jets according to different inclinations.

In this case, we recover the particles strongly magnetic 5 that stay in touch the most long time with the 16 magnetic drum and a mix depleted in strongly magnetic particles 19 thanks to an adjustable tilt flap 20 separating the two jets sand.

The inclination of the flap 20 is adjusted so as to recover a maximum of strongly magnetic particles.

According to the same principle, the mixture depleted in strongly magnetic particles 19 is brought up to a second rotating drum 21 by a vibrating belt 22.

Two adjustable tilt flaps 23 and 24 are disposed downstream of the second drum in rotation so to recover strongly magnetic particles residuals 5, a mixture enriched in silica containing about 85% silica and a first rebalanced mixture olivine and silica 4 containing about 50% silica and 50% olivine.

The presence of the first drum 16 is preferable to prevent clogging of the second drum 21 and to obtain optimal separation at the level of second drum 21.

Referring to Figure 3, the rebalanced mixture in olivine and silica 4 is directed to the enclosure of heat treatment consisting of a bed oven fluidized 25 well known to those skilled in the art.

The fluidized bed furnace mainly comprises a metal enclosure thermally insulated by a refractory lining 26, caissons of fluidization 27, burner ramps consisting of perforated tubes equipped with injectors 28 and burners pilots 29 intended to ignite the air-gas mixture used in ramps and the standby of installation.

The fumes from combustion are directed in an afterburner chamber 30 in which a gas burner will bring them to a temperature of about 800 ° C to destroy the toxic compounds.

These fumes are then directed to a bag dust collector, not shown, via a energy recuperator for recovering energy calorific which is then used to warm the air fluidization.

Rebalanced mixture of olivine and silica 4 is introduced into the oven via a tube vibrating 30a for dosing the flow of the mixture injected.

This mixture 4 is then suspended and stirred thanks to the fluidization boxes 27. The ramps of burners then ensure the burning of resins coating the sand grains contained in the mixture 4 suspended in the oven at a temperature about 650 ° C.

The sand progresses in the oven during a time of treatment that the person skilled in the art can determine and who is preferably between 10 minutes and two hours then the sand is discharged to a cooler 32 by overflow.

The cooler 32 consists of two boxes not shown comprising a tubular exchanger not represented fed by water itself cooled in a cooling tower.

The cooler 32 also has a bed not shown fluidized which ensures the mixing of the sand in the cooling boxes.

At the outlet of the cooler, the temperature maximum of the rebalanced mixture of olivine and silica 7 is about 40 ° C and this mixture 7 is evacuated by overflow.

Referring to Figure 4, the rebalanced mixture olivine and silica 7 from the operation of heat treatment 6 undergoes the second sorting step magnetic 8 implemented by a second machine of magnetic sorting 33.

Similar to the first sorting step Magnetic 2 and the first sorting machine magnetic 13, the mixture 4 undergoes a first step of magnetic separation 34 followed by a second step of magnetic separation 35.

The first step of magnetic separation 34 is to recover the particles strongly 12 to facilitate the second step of magnetic separation 35.

For this, a first separation machine magnetic device 36 is constituted by a first drum in rotation comprising a metal casing to inside which magnets are arranged permanent rare earths.

The rebalanced mixture of olivine and silica 7 is brought to the first rotating drum 36 by a vibrating carpet 37 surmounted by a squeegee adjustable in height 38 to distribute evenly the sand on the carpet 37.

The mixture 7 is driven by the drum 36 and a adjustable tilt flap 40 disposed downstream of the drum 36 makes it possible to recover the particles strongly magnetic 12 and a particulate depleted mixture strongly metallic 39.

This mixture 39 is brought to a second drum rotating power 41 by a vibrating belt 42.

Three adjustable tilt flaps 43, 44 and 45 are arranged downstream of the second rotating drum 41 in order to recover strongly magnetic particles residual 12, the regenerated mixture of silica 11 containing more than 70% silica and may be used as hanging sand, the mixture of silica and of olivine 10 to undergo again the second magnetic sorting step 33 and mixing regenerated to olivine 9 containing more than 90% olivine.

This regenerated mixture of olivine 9 can then be used as contact sand to make a piece metal requiring contact sand as sand other than silica.

In the second sorting machine 33, the power magnets of the two drums 36, 41 is preferably greater than that of the magnets arranged in these two drums 16, 21 of the first sorting machine 13.

The separation process of the invention can in particular to apply to the manufacture of large cast steel dimensions such as the hearts of tracks most often made in a 13% steel manganese.

The present invention is not limited to the modes described above and in particular, the person skilled in the art will be able to implement any machine of magnetic separation to achieve the first 2 and second 8 stages of magnetic sorting and everything heat treatment device to carry to a temperature above 400 ° C the rebalanced mixture olivine and silica 4 from the first stage of magnetic sorting 2.

Claims (28)

A process for separating silica and olivine in a mixture containing it (1), said process comprising at least the following steps: at. a magnetic sorting step (2,8); and b. a heat treatment step (6), which results in particular a regenerated mixture of olivine (9) and a regenerated mixture of silica (11). Method according to claim 1, comprising at least the following steps: at. a first magnetic sorting step (2) of said mixture (1) from which results in particular a rebalanced mixture of olivine and silica (4) and a mixture enriched in silica (3); b. a heat treatment step (6) of the equilibrium mixture of olivine and silica (4) from step (a); and vs. a second step of magnetic sorting (8) of the mixture (7) resulting from step (b) from which results in particular a regenerated mixture of olivine (9) and a regenerated mixture of silica (11). A method as claimed in any one of the preceding claims, comprising at least, in order, the following steps: at. the first magnetic sorting step (2); b. the heat treatment step (6) of the first equilibrium mixture of olivine and silica (4) obtained in step (a); and vs. the second step of magnetic sorting (8) of the mixture (7) obtained in step (b). Process according to any one of preceding claims, wherein the mixture containing silica and olivine (1) is derived from the stall operation performed during manufacture of metal parts by molding and contains between 5 and 40% olivine, silica and particles strongly magnetic such as iron oxide particles. A method as claimed in any one of the preceding claims, wherein the first magnetic sorting step (2) comprises at least the following steps: (a1) a first magnetic separation step (14) for isolating strongly magnetic particles (5) from the mixture containing olivine and silica (1); and (a2) a second magnetic separation step (15) of the strongly magnetic particulate depleted mixture (19) obtained in step (a1) to remove the residual strongly magnetic particles (5) and obtain: the mixture enriched with silica (3), and the rebalanced mixture of olivine and silica (4). Process according to any one of preceding claims, wherein the mixture enriched with silica (3) is recycled and used as sand filling. Process according to any one of Claims 4 to 6, wherein the rebalanced mixture olivine and silica (4) contains approximately 50% silica and 50% olivine. Process according to any one of preceding claims, wherein the step of heat treatment (6) involves subjecting the mixture rebalanced to olivine and silica (4) at a temperature greater than 400 ° C. Process according to any one of preceding claims, wherein the step of heat treatment (6) consists in treating the mixture rebalanced to olivine and silica (4) in an oven fluidized bed (25) at a temperature of approximately 650 ° C. The method of claim 9 wherein the rebalanced mixture of olivine and silica (4) is cooled to a temperature below 50 ° C. A method as claimed in any one of the preceding claims, wherein the second magnetic sorting step (8) comprises at least the following steps: (c1) a first magnetic separation step (34) for separating the strongly magnetic particles (12) from the mixture (7) from the heat treatment step (6); and (c2) a second magnetic separation step (35) of the strongly magnetic particulate depleted mixture (39) obtained in step (c1) to remove the residual strongly magnetic particles (12) and obtain: the regenerated silica mixture (11), the regenerated mixture of olivine (9), and the mixture of olivine and silica (10). The method of claim 11, wherein the regenerated silica mixture (11) can be used as hanging sand. Process according to one of the preceding claims, characterized in that the regenerated mixture of olivine (9) contains more than 90% olivine and can be used as contact sand. Process according to any one of claims 12 and 13, wherein the silica mixture and olivine (10) obtained in step (c2) undergoes again the second step of magnetic sorting (8). Device for separating silica from olivine in a mixture (1) containing it, comprising at least: a magnetic sorting machine (13, 33), and a heat treatment chamber (25). Device according to claim 15, comprising at least: a first magnetic sorting machine (13), a heat treatment chamber (26), and a second magnetic sorting machine (33). Device according to claim 16, in which the first magnetic sorting machine (13), the heat treatment chamber (25) and the second sorting machine (33) are arranged in this order and in series. Device according to any one of claims 16 and 17, wherein the first machine of magnetic sorting (13) comprises a first separator magnetic (16) set to separate the particles strongly magnetic (12) of the mixture containing olivine and silica (1) and a second separator magnetic element (21) for separating, from the mixture depleted in strongly magnetic particles (12), particles strongly magnetic residuals (12) and obtain a silica-enriched mixture (3) and a rebalanced mixture olivine and silica (4). Device according to claim 18, in which first (16) and second (21) separators Magnetics are constituted by first (16) and second (21) metal drums magnetized in rotation on which the mixture to be separated (1, 19) circulates at a appropriate speed and by one or more shutters adjustable inclination (20, 23, 24) arranged downstream of the drums (16,21) so as to separate the different jets of sand thrown by the drums (16,21) and corresponding respectively to the particles strongly magnets (5), to the mixture enriched with silica (3) and rebalanced mixture of olivine and silica (4). Device according to claim 19, in which a flap (20) is disposed downstream of the first magnetic drum (16) and is arranged to separate of the mixture containing olivine and silica (1) the strongly magnetic particles (5). Device according to any one of claims 19 and 20, wherein two flaps are disposed downstream of the second drum (21) and are arranged to separate selectively from the mixture depleted in strongly magnetic particles (19), the strongly magnetic residual particles (5), the silica-enriched mixture (3), and the rebalanced mixture olivine and silica (4). Device according to any one of claims 15 to 21, wherein the enclosure of heat treatment (25) is constituted by an oven fluidized bed in which the rebalanced mixture olivine and silica (4) progresses in the oven by the fluidization at a temperature of about 650 ° C. Device according to claim 22, comprising a cooler (32) disposed downstream of the furnace to bring the rebalanced mixture into olivine and silica (4) at a temperature below 50 ° C. Device according to any one of 16 to 23, wherein the second machine of magnetic sorting (33) has a first separator magnetic (36) set to separate the particles strongly magnetic (12) of the mixture resulting from the treatment thermal (7) and a second magnetic separator (41) set to separate, from this mixture depleted in particles strongly magnetic (39), the particles strongly residual magnetic properties (12), the regenerated mixture silica (11), the regenerated mixture of olivine (9) and a mixture of olivine and silica (10). Device according to any one of claims 18 to 24, wherein the first and second magnetic separators (36, 41) are constituted by first (36) and second (41) magnetic metal drums in rotation on which the mixture to be separated (7,39) circulates at an appropriate speed and by one several adjustable tilt flaps (40, 43, 44, 45) arranged downstream of the drums (36,41) so as to separate the different jets of sand thrown by the drums (36,41) and corresponding respectively to the particles strongly magnetic (12) with the regenerated silica mixture (11), the regenerated mixture of olivine (9) and the mixture olivine and silica (10). Device according to claim 25 wherein a flap (40) is disposed downstream of the first drum magnet (36) and is set to separate mixture resulting from the heat treatment (7) circulating on the first drum the particles strongly magnetic (12). Device according to any one of claims 25 and 26, wherein three flaps (43, 44, 45) are arranged downstream of the second drum (41) and are set to selectively separate from the mixture depleted in strongly magnetic particles (39) circulating on the second drum (41) the particles strongly magnetic residual (12), the mixture regenerated silica (11), the regenerated mixture olivine (9) and the mixture of olivine and silica (10). Device according to any one of claims 24 to 27, including means for the mixture of olivine and silica (10) is introduced from new in the second magnetic sorting machine (33).

Images