• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The present invention relates to a cold crucible for induction heating apparatus for heating and melting materials such as metals. The crucible comprises a crucible body which has the general shape of a tube or test-tube, the peripheral wall of which comprises a plurality of arcs-shaped sections separated from one another by an air gap . Each section contains a cooling pipe circulating a cooling liquid to cool the crucible in operation. The present invention also relates to a cooling manifold which, in operation, is connected to the crucible body and which allows to distribute the cooling liquid in the various pipes. The invention also relates to a method of manufacturing the crucible. The field of the invention is in particular that of metallurgy and foundry.
    公开号:FR3076602A1
    申请号:FR1850147
    申请日:2018-01-09
    公开日:2019-07-12
    发明作者:Richard Haettel
    申请人:Centre National de la Recherche Scientifique CNRS;
    IPC主号:
    专利说明:

    "Cold crucible and associated cooling collector for induction heating device"
    The present invention relates to a cold crucible for an induction heating device for heating and melting materials such as metals. The crucible comprises a crucible body which has the general shape of a tube or a test tube, the peripheral partition of which comprises several sections in the form of circular arcs separated from one another by an air gap. . Each section contains a cooling pipe circulating a cooling liquid in order to cool the crucible in operation. The present invention also relates to a cooling manifold which, in operation, is connected to the crucible body and which makes it possible to distribute the cooling liquid in the various pipes. The invention also relates to a method of manufacturing the crucible. The field of the invention is in particular that of metallurgy and foundry.
    State of the art
    In the field of materials, it is very often necessary to melt materials, for example making alloys containing several metals or other materials. A known method is to use an induction heating device, formed of electrical conductors which surround a crucible called "cold", in which the material or materials to be heated, called "the load" are placed. The device comprises an inductor coil, surrounding the crucible, in order to generate a magnetic field inside the crucible and thus heat the charge by induction. The crucible is cooled to dissipate the heat coming from the charge and from the joule effect due to the current induced in it. The crucible has the general shape of a tube so that it comprises a peripheral partition forming an envelope. This partition is cut longitudinally so that the crucible is formed of several sections in the form of sectors, along the majority of the length of the crucible; the partition being arranged in a continuity of material at one end of the crucible. This sectoring of the crucible is necessary in order to electrically isolate the sections from each other, to induce eddy currents in the load and to prevent the magnetic field supplied by the inductor from being screened by the crucible. The device also includes a cooling manifold, or water box, distributing cooling water to pipes arranged in the peripheral partition of the crucible. Pipes are also connected by brazing to the crucible and the cooling manifold.
    However, these solders tend to deteriorate over time, which results in a potential source of contamination for the load contained in the crucible, significant leaks and therefore a limited lifespan.
    Document EP0398821 proposes brazing cooling tubes on an openwork ring for the flow of water between a water collector and the crucible; a cooling passage being arranged in each sector of the crucible to receive respectively a tube. This embodiment therefore makes it possible to reduce the number of solders but does not respond to the problem of leaks. In addition, it is difficult to produce brazing without altering the brazing of the adjacent tubes or pipes, in particular during the maintenance of the crucible.
    In addition, it is necessary to decontaminate the crucible after each use, or at least between loads of different natures, which is a complex operation and further reduces its lifespan. Contamination occurs due to the fact that residues and impurities are deposited on the walls of the crucible. In the event of a water leak, a violent reaction of the water with the material to be heated can occur, even up to the explosion.
    An object of the invention is to remedy all or part of the drawbacks of the state of the art. Another object of the invention is to propose a heating device with a cold crucible limiting the problems of lifetime, of sealing defects. It also aims to provide a device to facilitate maintenance compared to known devices. It also aims to propose operational conditions for manufacturing allowing the production of high purity materials. Finally, it aims to facilitate the use of a heating device in a cold crucible.
    Statement of the invention
    According to a first aspect of the invention, at least one of the abovementioned aims is achieved with a cold crucible for an induction heating device comprising a crucible body comprising: - a connection ring comprising an annular distribution region, - a tubular casing extending from the connection ring to define a heating volume, the casing being cut longitudinally so as to produce several separate sectors in order to induce eddy currents in the charge placed in the heating volume and d 'prevent the magnetic field provided by an inductor from being screened by the crucible, - coolant channels arranged longitudinally in the thickness of the crucible body so that each sector comprises at least one coolant channel.
    Each sector includes at least two coolant paths: a so-called "go" path and a so-called "return" coolant path. The coolant paths of each sector are formed by the at least one coolant channel. Said paths open into the annular distribution region so that said region has, for each sector, an orifice said "inlet" and an orifice said "outlet", the orifices being spaced apart from each other along in a radial direction of the crucible. The assembly thus forms along the periphery of the annular distribution region two distinct concentric regions around the longitudinal axis of the crucible, one of which communicates only with the outward path of the channels and the other communicates only with the return path of the canals.
    The crucible body is intended to be removably assembled with a cooling manifold via the connection ring, the manifold comprising coolant distribution elements connecting to the coolant channels, due to this assembly, to circulate said liquid between the collector and the channels.
    The crucible body has a one-piece structure composed of one and the same material having material continuity over at least two sectors.
    The cold crucible according to the invention allows easier use, compared to the crucible of the prior art, by limiting or even eliminating the brazing operations carried out on the crucible and by allowing connection with a collector without angular indexing during the coupling or keying system. Consequently, the crucible according to the invention limits or even eliminates leaks and offers an increased service life. Maintenance is also facilitated compared to known devices.
    For the rest and for the foregoing, the term "longitudinal" means a direction substantially parallel to the axis of the crucible body, more or less 15 degrees angular. This axis is generally vertical when the crucible is in the position of use and intended for vertical introduction or extraction. It typically corresponds to the center of the tubular casing, and / or of the induction winding which surrounds the crucible.
    Preferably, each channel comprises an attached channel partition inserted longitudinally into said channel. The partition forms a sealed or substantially sealed longitudinal contact with at least two distinct regions of the peripheral wall of said channel, so as to define the outward path and the return path on either side of said partition and extending longitudinally to the inside the same channel. The attached partition allows two coolant paths to be formed simply and in a small footprint. The partition is for example made of epoxy glass fabric or fiberglass composite.
    According to one embodiment, each channel partition has a planar shape. Its cross section is substantially linear and straight in one direction. According to another embodiment, each channel partition has a two-dimensional shape. By two-dimensional is meant a shape whose cross section is non-rectilinear, for example curved, or comprising at least one element of non-zero thickness on one face of the partition.
    Each channel partition is arranged in its channel so that an imaginary geometric plane included in the thickness of the partition is substantially tangential to an imaginary cylinder of revolution concentric with the crucible. This characteristic makes it possible to form in the connection zone of the connection ring two distinct concentric regions around the longitudinal axis of the crucible, one of which communicates only with the outward path of the channels and the other of which communicates only with the return path. channels. The connection between the collector and the crucible can be made without indexing.
    According to one embodiment, each channel partition has a length substantially equal to or less than the length of the channels, and is designed to be inserted in a channel leaving a non-zero gap between the bottom of the channel and the so-called longitudinal end of passage of the channel partition. In this way the coolant can pass from the outward journey to the return journey. For example, each channel partition has a length at least equal to 75% of the length of a channel.
    Preferably, each channel comprises in its wall two distinct grooves arranged and configured to receive and position each partition in said channel. This characteristic allows reliable retention of the channel partitions in position, and allows them to be guided in said channel, improving the reliability of the crucible cooling.
    According to a second aspect of the invention, at least one of the abovementioned aims is achieved with a cold crucible for an induction heating device, characterized in that it comprises a crucible body comprising: - a connection ring comprising a annular distribution region, - a tubular envelope extending from the connection ring to define a heating volume, the envelope being cut longitudinally so as to produce several separate sectors, - coolant channels arranged longitudinally in the thickness of the crucible body so that each sector comprises at least one coolant channel.
    The crucible body is intended to be removably assembled with a cooling manifold via the connection ring, the manifold comprising coolant distribution elements which can be connected to the coolant channels to circulate said coolant.
    According to the second aspect of the invention, said crucible body has a one-piece structure composed of one and the same material having material continuity over at least two sectors.
    The cold crucible, according to the second aspect of the invention, allows easier use, compared to the crucible of the prior art, by limiting, even eliminating, the brazing operations carried out on the crucible. Consequently, the crucible according to the invention limits or even eliminates leaks and offers an increased service life. Maintenance is also facilitated compared to known devices.
    According to a variant of the first or second aspect of the invention, the crucible body consists essentially of: - a connection ring comprising an annular distribution region, - a tubular casing extending from the connection ring to define a heating volume, the casing being cut longitudinally so as to produce several separate sectors, and - coolant channels arranged longitudinally in the thickness of the crucible body so that each sector comprises at least one liquid channel cooling.
    According to another variant, the crucible is formed by several monoblock elements, each comprising several sectors formed in the same part. These multi-sector monoblock elements each form an angular portion of the crucible and are assembled together by removable mechanical means, for example individual screws or a common flange holding them all against the cooling manifold. Even in this variant, the number of mechanical fastenings is greatly limited, and good qualities of reliability and non-contamination are retained.
    Preferably, according to any aspect or variant, the crucible body has a one-piece structure composed of one and the same material having a continuity of material between the connection ring, the sectors of the envelope and the channels. This characteristic has the advantage of further improving the mechanical strength of the crucible and of retaining the geometry of the crucible body during its use. This parameter makes it possible to have a more homogeneous electromagnetic field and therefore more homogeneous heating of the load. When it comes to melting a material, better stability of the molten metal bath is obtained. This stability is particularly important when it is a question of manufacturing an alloy and of allowing each of the constituent elements of the alloy to dissolve, by diffusion in the liquid. If the instability of the molten metal bath becomes too great, the liquid metal is projected against the walls of the crucible and solidifies immediately which prevents its homogenization.
    According to the first or second aspect of the invention, the body of the crucible is made of an electrically conductive and thermal conductive material.
    According to a preferred embodiment, the body of the crucible is made of copper produced by hardening. In the prior art, the brazing operation on the crucible causes the copper to be annealed, which makes the crucible malleable. Without brazing performed on the copper crucible body according to the invention, the latter does not undergo annealing and thus remains rigid (without deformation). In addition, copper has very good thermal conductivity, which allows conduction cooling from the cooling channels to the ends of the sectors. Alternatively, the body of the crucible could be made of stainless steel.
    According to an embodiment compatible with the first aspect as the second aspect, the connection ring comprises on its periphery a crucible thread arranged to allow assembly by screwing so that a cooling manifold, provided with a thread collector which is complementary to it, can be screwed onto the crucible or vice versa. This characteristic makes it possible to mount and dismount the crucible cooling collector easily and quickly in order to improve the decontamination of the crucible after each use.
    Thus, the crucible body comprises a monobloc element, forming several sectors which are all separated from one another by longitudinal cuts to their distal end and over their entire length except in the region of the connection ring, called the proximal region. Typically, each sector thus delimited comprises only one cooling channel. This cooling channel forms a blind hole, that is to say with a single end opening longitudinally, which blind hole is separated into two longitudinal paths by an attached partition which is inserted by this through end. Preferably, a single monobloc element forms all the sectors, and thus constitutes the entire envelope of the crucible body.
    For the rest and for the foregoing, the term “distal end” means an end situated near the bottom of the crucible body, and the term “proximal end” means an end situated near the connection ring of the crucible.
    According to a third aspect of the invention, which may conform in whole or in part to the first aspect or all or part of the second aspect of the invention, at least one of the abovementioned aims is achieved with a cooling manifold intended to cooperate with a cold crucible for an induction heating device, the crucible comprising: - a connection ring comprising an annular distribution region, - a tubular envelope extending from the connection ring to define a heating volume, the envelope being cut longitudinally so as to produce several separate sectors, - coolant channels arranged longitudinally in the thickness of the crucible so that each sector comprises at least one coolant channel comprising a channel partition, forming in each channel at at least two paths emerging respectively from two orifices spaced from each other along a rad direction ial of the crucible on the annular region of the connecting ring.
    The collector is characterized in that it has two collector cavities which are substantially circular and are arranged on the same face facing the connection ring, the collector cavities being offset in a radial direction by relative to the axis of the collector so that each collector cavity is located above a single orifice of each channel once the collector and the crucible assembled.
    The cooling collector according to the invention allows easier use, compared to the collector of the prior art, by allowing connection with a collector without indexing. Consequently, the collector according to the invention limits or even eliminates leaks and offers an increased service life. Maintenance is also facilitated compared to known devices.
    The two cavities are arranged so as to produce an inlet chamber and an outlet chamber which can be connected to a coolant circulation circuit.
    Preferably, the collector comprises a circular collector partition separating said two collector cavities. Advantageously, a single collector partition separates said two collector cavities, which makes it possible to limit the space requirement and to facilitate assembly with respect to the crucible body. For example, said manifold partition bears against said ends of the sealing of the channel partitions. According to one embodiment, the manifold wall has a cone shape.
    According to one embodiment, the collector comprises, around the collector cavities, a collector thread arranged to allow assembly by screwing so that a crucible body also comprising a complementary crucible thread can be screwed onto the collector or vice versa . This feature makes it very easy to connect the cooling manifold to a body of the crucible.
    Preferably, the cooling manifold is made of stainless steel.
    According to a fourth aspect of the invention, one of the abovementioned aims is achieved by an induction heating device comprising a cold crucible body according to all or part of the first aspect or all or part of the second aspect and a cooling collector according to all or part of the third aspect of the invention. According to this fourth aspect, they are arranged so that, when assembled together, the coolant distribution elements of the collector are connected to the coolant channels of the crucible body
    According to a fifth aspect of the invention there is provided a method for manufacturing a cold crucible for an induction heating device, the crucible comprising a crucible body communicating with a cooling manifold, the crucible body comprising a tubular casing s extending from the cooling manifold and surrounding a heating chamber included in a heating volume, the casing being cut longitudinally so as to produce several separate sectors, cooling liquid channels arranged longitudinally in the thickness of the crucible so that each sector comprises at least one coolant channel, the method comprising the following steps: - supplying one or more one-piece or blank starting parts, made of a thermally and electrically conductive material, preferably copper, for example a solid circle or a tube, - for each starting part, machine the part to the di desired external and internal dimensions, depending on the desired crucible size, to produce a crucible body forming a connection ring from which the tubular casing extends.
    The manufacturing process comprises, in this order or in another, the following stages: - making a crucible thread around the periphery of the connection ring, - making bores corresponding to the coolant channels and opening into the surface of the connection ring, - make two diametrically opposite grooves in the wall of each channel. - Make longitudinal cuts on the envelope through the entire thickness of the envelope, the cuts extending between the connecting ring and up to the end of the crucible body opposite to the ring.
    The manufacturing method according to the invention makes it possible to produce a crucible body proposing operational manufacturing conditions making it possible to produce materials of high purity.
    Preferably, a round of high purity copper is chosen. The preferred copper grades are between the Cu-Al and Cu-C2 ranges according to the AFNOR standard, that is to say: - Cu-Al: used for the manufacture of wires, bars and tubes for electrical use, high electrical conductivity, good resistance to chemical agents, - Cu-C2: very high purity copper, electrical and electronic use, good solderability, refined oxygen-free copper; the CU-C2 category, with its greater purity and above all its oxygen limited to 5 ppm, is better suited to applications requiring a high vacuum.
    The Cu-C2 grade is the preferred grade because the purest and the one which degasses the least, and is particularly suitable for use under ultra-high vacuum.
    The large dimensions are preferably machined by turning and milling.
    The channels are preferably made with a deep drilling machine. The bores must be particularly careful in order to respect a deviation from the axis of 0.1 mm maximum for a depth of 100 mm. Then, the bores must be machined with an H7 tolerance (according to the ISO system), that is to say allowing a sliding assembly, in order to allow the introduction of a calibrated tool to make the two diametrically opposite grooves.
    Once machining is complete, a channel partition can be inserted into each channel. For example, the channel partition is made of composite materials based on resin and glass fibers. It is for example machined by milling and is adjusted in order to obtain a sliding fit in the grooves of each channel.
    To introduce the channel partitions more easily, it is possible to use a mallet.
    According to one embodiment, the grooves can be made so as to have a longitudinal depth slightly less than the depth of each channel so that, when the channel partition is put in place, the bottom of the channel corresponds to a passage area between the outward journey and the return journey of the canal.
    According to a first embodiment of the channel partitions, the distal ends of the grooves provide an axial stop for the positioning of said partition which makes it easier to assemble. The channel partitions have identical dimensions over all their lengths. The lengths of the partitions are identical to the lengths of the depths of the grooves so that the upper or proximal end of each partition is flush with the surface of the connecting ring.
    According to a second embodiment of the channel partitions, these have, near their proximal end, one or two shoulders. In this embodiment, the channels can be made with or without grooves. In addition, a cut is made in a groove (or both grooves, or near the opening) of each channel and on the annular region so that each shoulder rests on a cut.
    According to a variant of the second embodiment, a circular machining is carried out on the transverse face on which the coolant channels open out so as to form a circular connection groove, when the bores are not yet produced, and a succession of grooves between the openings of the bores when the bores are made.
    Optionally, a hardening resin is introduced into said connection grooves or the notches so as to fill them to seal between two channels. The resin is applied until it reaches the height of the proximal end of the channel partitions. The resin improves the seal on the one hand between the inlet and the outlet of each channel and on the other hand more generally between the crucible body and the cooling manifold. The resin is preferably of the type sufficiently rigid to be able to be machined and to be able to resist coolant. For example, the resin is Stycast® 2850FT.
    In order to apply the resin, plugs are used blocking the orifices of each channel. Preferably, each plug has a slot whose shape and thickness are complementary to the shape and thickness of the channel partitions. For example, the plugs are made of polytetrafluoroethylene called "PTFE".
    Once the resin has been applied, it may be necessary to remove the excess resin by machining so as to create a continuous flat surface between the proximal ends of the partitions and the resin, when connection grooves (between each pair of channels along the around the annular region) are made, or between the proximal ends of the partitions, the resin and the surface of the annular region of the connecting ring, when notches are made.
    A flat span along the diameter comprising the channel partitions is necessary so that a manifold partition, separating the outward and return cavities of the cooling manifold, comes to bear on said flat span (comprising the channel partitions) and makes a continuous contact so as to form a seal when the cooling manifold is connected to the crucible body. Thus the coolant can circulate between said coolant collector and said crucible body without the coolant crossing one of the paths outside the passage provided for this purpose.
    In addition, said crucible body has a second bearing formed on the annular region of the connection ring between the heating volume and the orifices of the channels. The second scope delimits the border between the heating volume and the channels. It is made in such a way that a collector barrier comes to bear on said second bearing surface and makes a continuous contact so as to form a seal with respect to the heating volume. Preferably, the second bearing is a chamfer. This characteristic has the advantage of facilitating the centering and therefore the positioning of the cooling manifold relative to the crucible body. The chamfer also has the advantage of being compact.
    Preferably, each end of the manifold wall and of the manifold barrier includes an O-ring in order to provide the seal.
    The manufacturing process according to the invention makes it possible to produce any type of crucible; for example straight crucibles without bottom, called "continuous casting" or also crucibles of the "pocket" type called "semi-levitation" for example hemispherical and conical.
    Preferably, the following are made: - so-called “high” longitudinal cutouts on the casing through the entire thickness of the casing, the cutouts extending between the connecting ring towards the end of the crucible body opposite to the ring without reaching the distal end of the crucible body, - so-called "low" electro-erosion longitudinal cuts forming slits, each slit crossing the entire thickness of the envelope, being narrow enough not to let escape a material to be heated, and extending in the extension of the high cutouts to the distal end opposite to the connection ring.
    The slits are cut according to the following steps: - place a core inside the crucible body, - close the outside of the high cutouts at least in their part which connects with the slits, for example by placing a ribbon of '' adhesive sealing around the envelope of the crucible body, - fill the upper cutouts with resin, - cut the slots by electroerosion, in particular with wire, - remove or dissolve the resin.
    For example, each slot has a width of 0.35 millimeter. When cutting the slots by EDM, it is imperative to keep the sectors in position, otherwise they will deform during cutting (loosening of internal stresses in the copper).
    To keep the sectors in position, a cylindrical core is inserted inside the crucible, the core being adjusted to the internal diameter of the crucible body. For example, the core is made of polytetrafluoroethylene called "PTFE". Preferably, the core is placed in the body of the crucible at the level of the high cutouts and at a distance from the area where the slits will be made. Then, an adhesive tape is inserted on the outside of the crucible body opposite the core. Finally, a resin is applied in the high cutouts. This implementation makes it possible to bring the sectors together.
    When cutting by EDM, it is essential that the wire allowing the cutting cannot come into contact with resin, so that the cutting of the slots is not disturbed.
    Once the slits have been made, the resin is dissolved using an appropriate solvent.
    The cooling manifold is preferably made in two parts. These two parts are machined separately by turning and milling and then assembled by welding. Once assembled, the collector defines two circular cavities.
    Description of the Figures and Embodiments Other characteristics and advantages of the invention will appear on reading the detailed description of implementations and embodiments that are in no way limitative, with reference to the appended figures in which: , lb, le and ld are views of an induction heating device comprising a crucible known as a “pocket” connected to a cooling collector according to an embodiment of the invention, said crucible comprising longitudinal cuts in the envelope of the crucible forming separate sectors, each sector comprising a coolant channel, FIG. 1a being a front view of said device, FIG. 1b being a sectional view of the device of FIG. 1a along a longitudinal cutting plane passing through the axis of said device and by diametrically opposite cutouts, the figure being a perspective view and slightly in low angle view d u device according to Figure la, Figure ld being a perspective view in section of the device of Figure la along a longitudinal sectional plane passing through the axis of said device and through diametrically opposite channels; - Figures 2a and 2b are views of a crucible showing a crucible body comprising a connecting ring and an envelope according to an embodiment of the invention in accordance with Figures la to ld, Figure 2a being a front view of the crucible body, FIG. 2b being a sectional view of a crucible body according to FIG. 2a according to a longitudinal section plane passing through the axis of said crucible body and through diametrically opposite cutouts; - Figure 3 is a sectional view of a crucible body according to Figure 2a in a section with perpendicular planes, the first plane of which passes through the axis and through diametrically opposite cutouts of the crucible body and the second plane of which passes through the envelope, FIG. 3 showing in particular sectors separated from the envelope, each sector comprising a channel according to an embodiment of the invention, - FIG. 4 is an enlargement of part of the ring connecting the crucible body of Figure 2b, showing part of an annular region of said ring, said region comprising a connecting groove; - Figure 5 is an enlargement of a sector seen in section of Figure 3, showing cutouts at the bottom of the crucible body; - Figure 6a is a sectional view of a crucible body according to Figure 2a along a longitudinal section plane passing through the axis of said crucible body and through diametrically opposite channels, an attached channel partition being visible in each channel; - Figure 6b shows an example of channel partition reported front view; - Figures 7a, 7b shows a first tubular part of the cooling manifold according to one embodiment, intended to be connected to a second part of said manifold, Figure 7a being a front view of said first part, Figure 7b being a sectional view of the part of FIG. 7a showing a bore provided for the passage of the materials to be heated; - Figure 8 is a sectional view of a second part of the cooling manifold comprising a manifold partition, a coolant inlet port and a coolant outlet port; - Figure 9 is a perspective view of a crucible body comprising coolant channels into which are inserted attached channel partitions whose proximal ends are visible; FIG. 10 is a perspective view of a channel plug according to one embodiment, the plug comprising a slot intended to receive a proximal end of an attached channel partition; - Figures 11a and 11b show a crucible body called "bottomless", according to one embodiment, comprising a connection ring and an envelope, Figure 11a being a front view, Figure 11b being a sectional view of crucible body of Figure 11a along a section plane passing through the axis and diametrically opposite cutouts of the crucible body; - Figure 12 an enlargement of an induction heating device seen in section of Figure ld, showing the communication of the coolant between the cooling manifold and the body of the crucible.
    Description of an exemplary embodiment
    The embodiments which will be described below are in no way limiting; it will be possible in particular to implement variants of the invention comprising only a selection of characteristics described subsequently isolated from the other characteristics described, if this selection of characteristics is sufficient to confer a technical advantage or to differentiate the invention from in the prior art. This selection comprises at least one characteristic, preferably functional, without structural details, or with only a part of the structural details if this part only is sufficient to confer a technical advantage or to differentiate the invention from the state of the prior art.
    In particular, all the variants and all the embodiments described can be combined with one another if there is nothing technically opposed to this combination.
    Figures la, lb, le and ld illustrate an induction heating device 1 intended to melt materials to make alloys or to melt pure metals to make castings in molds, or to refine in a particular atmosphere during melting. The heating device comprises a crucible 10 called "cold" intended to contain said materials to be heated, also called "the load" (not visible in the figures). The load is heated by a coiled inductor (not shown) around the crucible 10 and a generator (not shown). In known manner, the heating device also comprises a cooling manifold 30 distributing a cooling liquid in the crucible 10 connected to the latter.
    We will first describe a crucible 10 of the “pocket” or “semi-levitation” type. Referring to Figures la, lb, le, ld, 2a, 2b, 6a and 9, the crucible 10 comprises a crucible body 11 containing the material to be heated.
    The crucible body 11 comprises a connection ring 12 intended to allow the mechanical connection on the one hand and, on the other hand, the flows of cooling liquid between the crucible body and the cooling manifold. The connecting ring is a circular portion of the crucible body and is continuous in material along its circumference. The connecting ring will be described in more detail below.
    The crucible body 11 comprises a tubular casing 14 extending axially from the connection ring 12 to define a heating volume. In the case of a crucible of the "pocket" or "semi-levitation" type, the crucible body 11 comprises a crucible bottom 110 that is substantially conical. The envelope 14 is cut longitudinally so as to produce several separate sectors 16. With reference to FIGS. 1b, 2b, 3 and 5, longitudinal cuts called "high" or interstices 18 are made in radial directions relative to the axis longitudinal of the crucible body and in the thickness of the tubular casing 14 so that the remaining casing portions form angular sectors of casing along the circumference of the casing 14 (see in particular Figures 3 and 5). With reference to FIGS. 1b, 2b and 3, the longitudinal cuts 18 are made with an equal transverse depth up to the distal end of the body of the crucible so that the bottom 110 of the body of the crucible is not cut over its whole thickness but according to a cut having a width which can be substantially identical to the width of a cut 18; since the bottom of the crucible 110 is conical. According to another embodiment, the cutting width at the bottom 110 of the crucible body can be slightly different, either to increase the performance of the crucible, or to improve cooling.
    The high cutouts 18 have a width substantially equal to 3 to 4 millimeters. This makes it possible to limit the pressure drops, especially in the case of production under vacuum.
    The bottom of the crucible 110 also has longitudinal cuts. With reference to FIGS. 1b, 2b and 5, longitudinal cutouts or slits 19 are made in radial directions relative to the longitudinal axis of the crucible body and in the thickness of the bottom of the crucible body 110 so that the portions bottom of the remaining body form angular envelope sectors along the circumference of the bottom 110 of the crucible body. The slots 19 are produced substantially in the extension of the high cutouts 18 so that the sectors 16 are separated from the connecting ring up to the distal end of the crucible body. The slots 19 have a width substantially equal to 0.35 millimeter.
    According to the example shown, the crucible body has an internal diameter of 50 millimeters and has 16 sectors. The crucible body shown in FIGS. 1b, 1d, 2b and 6a has at its distal end a pouring opening 111 allowing the charge to be poured by gravity into an ingot mold located below. In use, a retractable finger (not shown) obstructs the end of the crucible body, for example a finger itself cooled.
    The crucible body comprises a coolant channel 15 in each sector 16. With reference to FIGS. 1d, 3 and 6a, each cooling channel 15 is arranged longitudinally in the thickness of each sector. The channels 15 have a tubular shape.
    With reference to FIGS. 1d and 6a, the channels 15 extend to the bottom of the crucible body 110 so as to form a blind hole, the bottom of which, called the bottom of the channel, is designated by the reference 151. With reference to FIGS. 3 and 6a, the channels 15 open onto the upper surface of the connection ring 12 comprising an annular region 120.
    The crucible body comprises several added channel partitions 20 so that each partition is designed to be inserted in a channel 15. In addition, each channel 15 is arranged and configured to receive a channel partition 20. It is inserted longitudinally in each channel and forms a tight longitudinal contact with at least two distinct regions of the peripheral inner wall of said channel. From the point of view of the bottom of the channel 151, the distal end of the channel partition 20 is at a distance from the bottom of the channel 151 so as to leave a passage. For example, the width of the passage is substantially equal to the radius of the channel. Once inserted into a channel and with reference to FIGS. 6a and 12, each channel 15 has, inside of it and on either side of the channel partition 20, a so-called “go” path 22 and a so-called “return” path 21 for the circulation of the cooling liquid in each sector of the crucible body. The coolant can circulate from the outward path to the return path through the passage, provided for this purpose, near the bottom of the channel 151. On the side of the connection ring (see figure 3 left side, 2b, 11b ), the paths open into the annular region 120. For each channel 15, the annular region has a so-called “inlet” orifice 24, corresponding to the entry of a outward path 22, and a so-called “outlet” orifice 23, corresponding to the exit from a return path 21. The inlet 24 and outlet 23 openings must be arranged one beside the other and aligned along a radial direction of the crucible.
    According to a preferred embodiment, each channel also has two diametrically opposite grooves so as to receive and position each channel partition 20. The grooves form two distinct regions extending longitudinally in each channel and form a tight longitudinal contact with the partition. channel 20 inserted into said channel.
    The added channel partitions have a rectangular shape whose thickness is very much less than its length or width so that they respectively form a plane. Referring to Figure 6b, the channel partition 20 has at its proximal end, intended to be close to the connecting ring, a widening of width 210 forming a shoulder. The widening of width 210 is provided to come into abutment against a notch made on the surface of the annular region 120. Preferably, two diametrically opposite notches are made on the annular region 120 in order to receive the shoulders of the channel partitions.
    Referring to Figures 3 and 9, each channel partition 20 is arranged in its channel 15 so that an imaginary geometric plane included in the thickness of the partition is substantially tangential to an imaginary cylinder of revolution concentric to the crucible. This characteristic makes it possible to radially delimit two regions for distributing the coolant, a first region for the inlet of the coolant comprising all the inlet orifices 24 and a second region for the return of the coolant comprising all the outlet orifices 23 It is then possible to connect a cooling manifold having no indexing, for example angular indexing, in order to connect the inlet and outlet streams of coolant between the cooling manifold and the crucible body.
    Referring to Figures 2b, 3 and 4, the annular region 120 comprises several connecting grooves 121 connecting the openings of the channels, or the notches provided for the channel partitions, so as to form a circular groove. The connection grooves 121 are provided to be filled with resin forming a seal, delimiting radially, with the proximal ends 200 of the channel partitions, the two regions for the distribution of the coolant. With reference to FIGS. 9 and 10, the orifices of the cooling channels are blocked by plugs 40 (see FIG. 9 showing a plug blocking a channel). Each plug 40 has a substantially cylindrical outer shape whose outer diameter is substantially equal to the inner diameter of each channel. Each plug 40 comprises a partition slot 41 intended to receive a proximal end of a channel partition (see FIG. 10), thus allowing the introduction of the plug into the channel comprising a partition so as to block the orifices of the channel. Once the channels are closed, the connection grooves 121 are filled with resin. Once the resin has hardened, the plugs 40 are removed and the excess resin is removed, for example by machining, in order to obtain a flat surface and thus serve as a junction surface with a circular partition of cooling manifold. Preferably, the production of the flat span may include the machining of the proximal end of the channel partitions.
    Referring to Figures 2a, 2b, 6a, the connecting ring 12 has on its periphery a connecting surface 13 comprising a crucible thread arranged to allow assembly by screwing with a cooling manifold comprising a complementary manifold thread so that the crucible can be screwed on a collector or vice versa.
    Figures 11a and 11b show another type of crucible called "bottomless" or "continuous casting". In this embodiment, the crucible body does not have a conical crucible bottom 110, but has a heating volume having a constant internal diameter up to the end of the crucible body. For the rest, the crucible body of Figures 11a and 11b includes the same characteristics as a crucible called "pocket" or "semi-levitation" as described in the other figures.
    We will now describe a cooling manifold 30 arranged and configured to be connected both mechanically and with respect to the circulation of the coolant flows between said manifold and a crucible body described above. From a mechanical point of view and with reference to FIG. 8, the cooling manifold comprises a first peripheral part 30a which has, on an internal face, a manifold thread 31 complementary to the crucible thread so that they can s '' assemble by screwing.
    With reference to FIGS. 1b and 12, the cooling manifold 30 comprises two manifold cavities forming the distribution elements: a so-called “go” cavity 34 and a so-called “return” cavity 33 which are substantially circular and which are arranged opposite. the annular region 120 of the connecting ring. The cavities 33, 34 are offset in a radial direction relative to the axis of the manifold so that the outward cavity 34 is opposite the inlet orifices 24, and the return cavity 33 is opposite the outlet orifices 23. The cavities 33, 34 are separated by a circular collector partition 32. The collector partition 32 is designed to come into abutment against the proximal ends known as “sealing” 200 of the channel partitions (see FIG. 1b and 12). With reference to FIGS. 1b, 1d and 12, the manifold partition 32 has a conical shape.
    The collector also comprises an inlet orifice 38 for the coolant communicating with the outward cavity 34, and an outlet orifice 37 for the coolant communicating with the return cavity 33 (see Figures 1b and 8). The return cavity 33 is delimited radially by the manifold partition 32 and by an internal edge 123 of the connection ring 12 (see FIGS. 1b and 12).
    With reference to FIGS. 7a, 7b, the collector comprises a second collector piece 30b which comprises a tube 35, the upper end of which comprises a flange 350. The volume delimited by the tube 35 corresponds to an insertion passage 36 via which the charge is inserted before being introduced into the heating volume delimited by the tubular casing (Figures 1b and 1d). The second manifold piece 30b is intended to be welded to the first manifold piece 30a (see Figure 8). Preferably, the first collector piece 30a comprises a counterbore 301 on its upper end. The cooling collector is produced by welding the flange 350 of the second collector piece 30b into the counterbore 301 of the first collector piece 30a, so as to obtain the cooling collector 30 shown in FIGS. 1b and 1d.
    The outward cavity 34 is thus delimited radially by the manifold partition 32 and by the wall of the tube 35, see FIG. 12.
    With reference to FIG. 12, once the cooling manifold 30 is connected to the crucible body 11, the manifold partition 32 presses on the proximal ends of the channel partitions and the resin forming a seal, and the tube 35 presses on a chamfer 124 produced on the annular region 120.
    With reference to FIGS. 1b and 1d, the collector 30 is arranged concentrically with respect to the crucible body 11. The cooling collector 30 comprises an insertion passage 36 via which the charge is inserted before being introduced into the volume heating delimited by the tubular casing.
    权利要求:
    Claims (15)
    [1" id="c-fr-0001]
    claims
    1. Cold crucible (10) for an induction heating device (1), characterized in that it comprises a crucible body (11) comprising: a connection ring (12) comprising an annular distribution region (120), a tubular casing (14) extending from the connection ring (12) to define a heating volume, the casing being cut longitudinally so as to produce several separate sectors (16), coolant channels (15 ) arranged longitudinally in the thickness of the crucible body so that each sector (16) comprises at least one coolant channel (15), each sector comprising at least two coolant paths, one outward path (22) and a return path (21) of the coolant, formed by the at least one coolant channel (15), said paths opening into the annular distribution region (120) so that said region (120) pres ente, for each sector, an inlet orifice (24) and an outlet orifice (23), the orifices being spaced from one another along a radial direction of the crucible, thus forming along the periphery of the annular distribution region two distinct regions concentric around the longitudinal axis of the crucible, one of which communicates only with the outward path of the channels and the other communicates only with the return path of the channels, the crucible body being intended to be removably assembled with a cooling manifold (30) via the connection ring (12), the manifold (30) comprising coolant distribution elements connecting to the coolant channels (15), made of this assembly, to circulate said liquid between the collector and the channels, and in that said crucible body (11) has a one-piece structure composed of a single and same material having a continuity é of material on at least two sectors.
    [2" id="c-fr-0002]
    2. Crucible (10) according to claim 1, characterized in that each channel comprises an attached channel partition (20) inserted longitudinally in said channel (15) and forming a tight longitudinal contact with at least two distinct regions of the peripheral wall of said channel, so as to define the outward path (22) and the return path (21) on either side of said partition (20) and extending longitudinally inside the same channel (15).
    [3" id="c-fr-0003]
    3. Crucible (10) according to claim 2, characterized in that each channel partition (20) has a planar or two-dimensional shape and is arranged in its channel (15) so that an imaginary geometric plane included in the thickness of the partition is substantially tangential to a cylinder of imaginary revolution concentric with the crucible.
    [4" id="c-fr-0004]
    4. Crucible (10) according to claim 2 or 3, characterized in that each channel partition (20) has a length substantially equal to or less than the length of the channels, and is designed to be inserted into a channel leaving a gap not zero between the bottom (151) of the channel and the longitudinal end known as the passage of the channel partition.
    [5" id="c-fr-0005]
    5. Crucible (10) according to one of claims 2 to 4, characterized in that each channel (15) comprises in its wall two distinct grooves arranged and configured to receive and position each partition (20) in said channel.
    [6" id="c-fr-0006]
    6. Crucible (10) according to any one of the preceding claims, characterized in that the connection ring (12) comprises on its periphery a crucible thread (13) arranged to allow assembly by screwing so that a cooling collector (30) provided with a collector thread (31) which is complementary thereto can be screwed onto the crucible or vice versa.
    [7" id="c-fr-0007]
    7. Cooling manifold (30) intended to cooperate with a cold crucible (10) for an induction heating device (1), the crucible comprising: a connection ring (12) comprising an annular distribution region (120), a tubular casing (14) extending from the connecting ring (12) to define a heating volume, the casing being cut longitudinally so as to produce several separate sectors (16), coolant channels (15) arranged longitudinally in the thickness of the crucible so that each sector (16) comprises at least one coolant channel comprising a channel partition (20), forming in each channel at least two paths (21, 22) opening out respectively through two orifices (23, 24) spaced from each other along a radial direction of the crucible, the collector being characterized in that it has two collector cavities (33, 34) which are substantially cir and are arranged on the same face facing the connection ring, the manifold cavities being offset in a radial direction relative to the axis of the manifold so that each manifold cavity (33, 34) is located above a single orifice (23, 24) of each channel once the collector and the crucible assembled.
    [8" id="c-fr-0008]
    8. Collector (30) according to the preceding claim, characterized in that it comprises a circular collector partition (32) separating said two collector cavities (33, 34), said collector partition (32) bearing against said sealing ends (200) of the channel partitions.
    [9" id="c-fr-0009]
    9. Collector (30) according to claim 7 or 8, characterized in that it comprises, around the collector cavities, a collector thread (31) arranged to allow assembly by screwing so that a crucible body ( 10) also comprising a complementary crucible thread (13) can be screwed onto the collector (30) or vice versa.
    [10" id="c-fr-0010]
    10. Induction heating device (1) comprising a cold crucible body (10) according to one of claims 1 to 6 and a cooling collector (30) according to one of claims 7 to 9 arranged so that when 'they are assembled together, the coolant distribution elements (33, 34) of the collector (30) are connected to the coolant channels (15) of the crucible body (10).
    [11" id="c-fr-0011]
    11. Method for manufacturing a cold crucible (10) for an induction heating device, the crucible comprising a crucible body (11) communicating with a cooling manifold (30), the crucible body comprising a tubular casing (14 ) extending from the cooling manifold and surrounding a heating chamber included in a heating volume, the casing being cut longitudinally so as to produce several separate sectors (16), cooling liquid channels (15) arranged longitudinally in the thickness of the crucible so that each sector (16) comprises at least one coolant channel (15), the method comprising the following steps: supplying one or more one-piece or blank starting parts, made of a thermal conductive material and electric, preferably copper, for example a solid circle or a tube, for each starting part, machine the part to the external dimensions es and interior desired, depending on the desired crucible size, to produce a crucible body forming a connection ring which extends the tubular casing, as well as, in this order or in another, the following steps: making a thread crucible (13) on the periphery of the connection ring (12), make bores corresponding to the coolant channels (15) and opening into the surface of the connection ring (12), make two grooves, diametrically opposite, in the wall of each channel (15), make longitudinal cuts (18, 19) on the envelope (14) through the entire thickness of the envelope, the cuts extending between the ring of connection (12) and up to the end of the crucible body opposite the ring.
    [12" id="c-fr-0012]
    12. Method according to claim 11, characterized in that a circular machining is carried out on the transverse face on which the channels open so as to form a circular connection groove (121), when the bores are not yet produced, and a succession of grooves (121) between the openings of the bores when the bores are made, and in that a hardening resin is introduced into the grooves (121) so as to fill them to seal between two channels.
    [13" id="c-fr-0013]
    13. Method according to claim 11 or 12, characterized in that one introduces a channel partition in each channel after making the grooves.
    [14" id="c-fr-0014]
    14. Method according to one of claims 11 to 13, characterized in that one realizes: longitudinal cuts called "high" (18) on the envelope (14) through the entire thickness of the envelope, the cutouts extending between the connecting ring (12) towards the end of the crucible body opposite the ring without reaching the distal end of the crucible body, longitudinal cuts called "low" by EDM forming slots ( 19), each slit passing through the entire thickness of the envelope, being sufficiently narrow so as not to let escape a material to be heated, and extending in the extension of the high cutouts (18) up to the distal end opposite the connecting ring.
    [15" id="c-fr-0015]
    15. Method according to the preceding claim, characterized in that, the cutting of the slots (19) is carried out according to the following steps: placing a core inside the crucible body (11), closing the outside of the tall cutouts at less in their part connecting with the slots, for example by placing an adhesive sealing tape around the envelope of the crucible body, filling the upper cutouts with resin, cutting the slots by electroerosion, in particular with wire, removing or dissolve the resin.
    类似技术:
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    同族专利:
    公开号 | 公开日
    EP3737901B1|2022-02-09|
    WO2019137840A1|2019-07-18|
    FR3076602B1|2020-01-24|
    EP3737901A1|2020-11-18|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    EP0398821A2|1989-05-08|1990-11-22|Howmet Corporation|Segmented induction skull melting crucible and method|
    CN206488623U|2016-08-31|2017-09-12|沈阳真空技术研究所|The cold crucible of metal induction melting|CN113461307A|2021-06-21|2021-10-01|中国原子能科学研究院|Container and material processing equipment|
    CN113461306A|2021-06-21|2021-10-01|中国原子能科学研究院|Container and material processing equipment|
    法律状态:
    2019-01-30| PLFP| Fee payment|Year of fee payment: 2 |
    2019-07-12| PLSC| Publication of the preliminary search report|Effective date: 20190712 |
    2020-01-30| PLFP| Fee payment|Year of fee payment: 3 |
    2021-01-28| PLFP| Fee payment|Year of fee payment: 4 |
    2022-01-31| PLFP| Fee payment|Year of fee payment: 5 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1850147|2018-01-09|
    FR1850147A|FR3076602B1|2018-01-09|2018-01-09|COLD CRUCIBLE AND ASSOCIATED COOLING COLLECTOR FOR INDUCTION HEATING DEVICE|FR1850147A| FR3076602B1|2018-01-09|2018-01-09|COLD CRUCIBLE AND ASSOCIATED COOLING COLLECTOR FOR INDUCTION HEATING DEVICE|
    EP19700015.1A| EP3737901B1|2018-01-09|2019-01-02|Cold crucible and associated cooling manifold for an induction heating device|
    PCT/EP2019/050046| WO2019137840A1|2018-01-09|2019-01-02|Cold crucible and associated cooling manifold for an induction heating device|
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