CN101116901A - Square cold crucible for the continuous fusion cast and oriented crystallization - Google Patents
Square cold crucible for the continuous fusion cast and oriented crystallization Download PDFInfo
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- CN101116901A CN101116901A CNA2007100727143A CN200710072714A CN101116901A CN 101116901 A CN101116901 A CN 101116901A CN A2007100727143 A CNA2007100727143 A CN A2007100727143A CN 200710072714 A CN200710072714 A CN 200710072714A CN 101116901 A CN101116901 A CN 101116901A
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Abstract
The invention provides a constantly casting and directionally crystallizing square cold crucible. The invention relates to a constantly casting and directionally crystallizing quadrate cold crucible which overcomes the defects that during the making of square billet, the magnetic line of force at the corner part of the square cavity of the cold crucible is screened and the magnetic flux density at the corner part is the smallest. The invention comprises a crucible, a magnetic coil, a cooling water distributor and a cooling water return channel. The magnetic coil coils on the outer surface of a barrel-shaped body of the crucible. The wall of the barrel-shaped body of the crucible is provided with multiple downwards water ducts and upwards water ducts. The upper end of the each downwards water duct is communicated with a water outlet end of the cooling water distributor. The upper end of each upwards water duct is communicated with a water inlet end of the cooling water return channel. The lower end of each downwards water duct is only communicated with the adjacent lower end of the upwards water duct. The barrel wall of the crucible is provided with multiple permeability channels. The horizontal cross-section of the cavity of the crucible is a square and circular transitions are positioned between two optional sides of the square. The curvature radius of the circular transition is that R=2d2/H0 Sq.
Description
Technical field
The present invention relates to the cold crucible of a kind of continuous fusion-cast, crystallographic orientation.
Background technology
Cold crucible technology is the new technology of rising in recent years, it is that water jacketed copper crucible with distinguish places in the alternating electromagnetic field, utilize alternating electromagnetic field generated eddy current heat fusing metal, rely on electromagnetic force to make motlten metal and crucible wall keep soft and contact or contactless state, and furnace charge is carried out the technology of induction melting or electromagnetic shaping.Because smelting metal contacts with non-(soft) of sidewall of crucible, (so) can keep the high-purity of virgin metal and prevent the pollution of various interstitial elements in melting or forming process, the low-cost melting and the shaping of realization high-purity material.Therefore cold crucible technology is used widely in the material casting.
Be applied in the titanium aluminium base alloy blade on the engine because it is complex-shaped, the performance requirement height is difficult to direct cast form, but can utilizes the cold crucible method at first this material to be made square billet, and then by follow-up processing, is engine blade and uses.In order to cast out the titanium aluminium base alloy square billet, the intracavity section shape of cold crucible also will correspondingly manufacture square.But the problem that exists is if the intracavity section of cold crucible is square, and the electromagnetic field distribution is uneven in the inherent whole square area of cold crucible, is conductively-closed at corner part especially, and magnetic flux density minimum herein is unfavorable for that crudy improves.
Summary of the invention
The square cold crucible that the purpose of this invention is to provide a kind of continuous fusion-cast and crystallographic orientation, when casting square billet to overcome, the defective of corner part magnetic line of force conductively-closed in the cold crucible square inner chamber, magnetic flux density minimum.It comprises crucible body 1, solenoid 2, cooled water distributor 3 and cooling water return channel 4, solenoid 2 is coiled on the cylindrical body outer surface of crucible body 1, have many descending water hole road 1-1 and up water hole road 1-2 in the tubular body wall of crucible body 1, descending water hole road 1-1 and up water hole road 1-2 are parallel to the axial line of crucible body 1, the upper end of each descending water hole road 1-1 is communicated with a water side of cooled water distributor 3, the upper end of each up water hole road 1-2 is communicated with a water intake end of cooling water return channel 4, a plurality of descending water hole road 1-1 and up water hole road 1-2 are connected along the lower end that the cylindrical shell of crucible body 1 evenly is distributed as the up water hole road 1-2 that the lower end of a circle and each descending water hole road 1-1 only is adjacent, the barrel of crucible body 1 has many saturating magnet passage 1-3, the level cross-sectionn of the inner chamber of crucible body 1 is a square, be set to round-corner transition between foursquare any two limits, the radius of curvature at round-corner transition place is
, q in the formula
0---the induction heating power that unit volume is absorbed by melt material;
R---radius of curvature; H
0---unit volume is by the magnetic field intensity of melt material; S---by the melt material electrical conductivity; D---electric current penetrates by the melt material degree of depth.
Crucible corner part radius of curvature is the key factor that influences even fusing of stock of square and restraining force.Because the electromagnetic field distribution is uneven in whole square area, is conductively-closed at corner part especially, promptly the magnetic line of force is cancelled out each other herein, and this place is lower by the temperature of melt material, and electromagnetic confinement power is low, is unfavorable for by the quality of melt material.So be set to round-corner transition at corner part.As shown from the above formula, along with the increase of R, the melting capacity of this bight part becomes the increase of duplicate ratio.And the curvature in bight also can produce very big influence to the hump of alloy melt.The present invention utilizes the setting of round-corner transition, when having solved the casting square billet, and the defective of corner part magnetic line of force conductively-closed in the cold crucible square inner chamber, magnetic flux density minimum.
Description of drawings
Fig. 1 is a perspective view of the present invention, Fig. 2 is the vertical view of crucible body 1, Fig. 3 is the A-A cutaway view of Fig. 2, Fig. 4 is the short transverse Distribution of Magnetic Field schematic diagram of crucible body 1 bight inner edge, Fig. 5 is the short transverse Distribution of Magnetic Field schematic diagram of crucible body 1 inner edge portion central point, Fig. 6 is the short transverse Distribution of Magnetic Field schematic diagram of central point in the crucible body 1, and Fig. 7 is half place's short transverse Distribution of Magnetic Field schematic diagram of center to bight in the crucible body 1.
The specific embodiment
The specific embodiment one: specify present embodiment below in conjunction with Fig. 1 to Fig. 7.Present embodiment is by crucible body 1, solenoid 2, cooled water distributor 3 and cooling water return channel 4 are formed, solenoid 2 is coiled on the cylindrical body outer surface of crucible body 1, have many descending water hole road 1-1 and up water hole road 1-2 in the tubular body wall of crucible body 1, descending water hole road 1-1 and up water hole road 1-2 are parallel to the axial line of crucible body 1, the upper end of each descending water hole road 1-1 is communicated with a water side of cooled water distributor 3, the upper end of each up water hole road 1-2 is communicated with a water intake end of cooling water return channel 4, and a plurality of descending water hole road 1-1 and up water hole road 1-2 are connected along the lower end that the cylindrical shell of crucible body 1 evenly is distributed as the up water hole road 1-2 that the lower end of a circle and each descending water hole road 1-1 only is adjacent.Cooling water flows into descending water hole road 1-1 from cooled water distributor 3, then flows into the up water hole road 1-2 that is adjacent, and flows out to then in the cooling water return channel 4, because descending water hole road 1-1 and up water hole road 1-2 are provided with at interval, cooling effectiveness is higher.The barrel of crucible body 1 has many saturating magnet passage 1-3, and the level cross-sectionn of the inner chamber of crucible body 1 is a square, is set to round-corner transition between foursquare any two limits, and the radius of curvature at round-corner transition place is
, q in the formula
0---the induction heating power that unit volume is absorbed by melt material;
R---radius of curvature; H
0---unit volume is by the magnetic field intensity of melt material; S---by the melt material electrical conductivity; D---electric current penetrates by the melt material degree of depth.
From Fig. 4 to Fig. 7 as can be seen, the magnetic induction intensity at the inboard magnetic induction intensity in the angle of crucible body 1 and other position is more or less the same.
When specifically choosing structural parameters: can be decided to be 110mm to the height of crucible body 1, long * wide be 26mm * 26mm, the wall thickness of crucible body 1 is decided to be 15mm, the value of getting R is 6 millimeters, saturating magnet passage 1-3 begins from crucible body 1 bottom 5mm, getting length is 85mm, and the number of saturating magnet passage 1-3 on every limit is decided to be 3, adds up to 3 * 4=12 bar.Choosing of certain concrete structure parameter is not limited, and above-mentioned parameter is only for reference.
The specific embodiment two: specify present embodiment below in conjunction with Fig. 1 to Fig. 3.The difference of present embodiment and embodiment one is: saturating magnet passage 1-3 is along the short transverse setting of crucible body 1, many saturating magnet passage 1-3 are parallel to each other and evenly distribute along the circumferential exterior surface of crucible body 1, saturating magnet passage 1-3 is made up of the mica sheet 1-3-2 that runs through the slotted hole 1-3-1 between crucible body 1 inner surface and the outside face and be filled among the slotted hole 1-3-1, and the transverse shape of slotted hole 1-3-1 is " triangle " wide outside and narrow inside.
Because the cause of the magnetic line of force, the shape of cross section of saturating magnet passage 1-3 changes the magnetic permeability that can influence crucible, and the width requirement that cracks is suitable.The expansion of width can make the electromagnetic field that sees through increase, and improves heat fused and electromagnetic shaping ability, and is not ablated but the expansion of width should guarantee to take place between the leakage of metal bath or seam material.Therefore selected by " triangle " wide outside and narrow inside.Insert in the slotted hole 1-3-1 and in groove, pour into glass cement behind the natural mica sheet and shut, prevent that the molten metal in the crucible leaks outside under the high temperature; The outside is with ptfe sheet and glass wool cloth insulation and be coated with glass cement.
The specific embodiment three: specify present embodiment below in conjunction with Fig. 2.Present embodiment with the difference of embodiment two is: the transverse shape of slotted hole 1-3-1 is " triangle is communicated with rectangle ", and the drift angle that " triangle " is arranged on the outer surface of crucible body 1 and " triangle " is communicated with the minor face of " rectangle ".Present embodiment is applicable to when the wall thickness of crucible body 1 is big.
Claims (3)
1. the square cold crucible of continuous fusion-cast and crystallographic orientation, it comprises crucible body (1), solenoid (2), cooled water distributor (3) and cooling water return channel (4), solenoid (2) is coiled on the cylindrical body outer surface of crucible body (1), have road, many descending water holes (1-1) and road, up water hole (1-2) in the tubular body wall of crucible body (1), road, descending water hole (1-1) and road, up water hole (1-2) all are parallel to the axial line of crucible body (1), the upper end in each road, descending water hole (1-1) is communicated with a water side of cooled water distributor (3), the upper end in each road, up water hole (1-2) is communicated with a water intake end of cooling water return channel (4), road, a plurality of descending water hole (1-1) and road, up water hole (1-2) are connected along the lower end that the cylindrical shell of crucible body (1) evenly is distributed as the road, a up water hole (1-2) that the lower end in a circle and each road, descending water hole (1-1) only is adjacent, the barrel of crucible body (1) has many saturating magnet passages (1-3), the level cross-sectionn that it is characterized in that the inner chamber of crucible body (1) is square, be set to round-corner transition between foursquare any two limits, the radius of curvature at round-corner transition place is
Q in the formula
0---the induction heating power that unit volume is absorbed by melt material;
R---radius of curvature; H
0---unit volume is by the magnetic field intensity of melt material; S---by the melt material electrical conductivity; D---electric current penetrates by the melt material degree of depth.
2. the square cold crucible of continuous fusion-cast according to claim 1 and crystallographic orientation, it is characterized in that the short transverse setting of magnet passage (1-3) along crucible body (1), many saturating magnet passages (1-3) are parallel to each other and evenly distribute along the circumferential exterior surface of crucible body (1), saturating magnet passage (1-3) is made up of the mica sheet (1-3-2) that runs through the slotted hole (1-3-1) between crucible body (1) inner surface and the outside face and be filled in the slotted hole (1-3-1), and the transverse shape of slotted hole (1-3-1) is " triangle " wide outside and narrow inside.
3. the square cold crucible of continuous fusion-cast according to claim 1 and crystallographic orientation, the transverse shape that it is characterized in that slotted hole (1-3-1) is " triangle connection rectangle ", and the drift angle that " triangle " is arranged on the outer surface of crucible body (1) and " triangle " is communicated with the minor face of " rectangle ".
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101885053A (en) * | 2010-06-24 | 2010-11-17 | 西北工业大学 | Strong pulse current orientated solidification grain ultra-fining method and device |
CN101603776B (en) * | 2009-05-08 | 2011-02-09 | 北京航空航天大学 | Induction melting cold crucible |
CN103691912A (en) * | 2013-12-19 | 2014-04-02 | 东北大学 | Gold base alloy casting blank melting and casting integrated device and utilization method thereof |
CN104209483A (en) * | 2014-09-28 | 2014-12-17 | 哈尔滨工业大学 | Melting and electromagnetic constraint shaping system capable of performing efficient electro-thermal conversion |
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Publication number | Priority date | Publication date | Assignee | Title |
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JPH05212501A (en) * | 1992-02-04 | 1993-08-24 | Nippon Steel Corp | Method and device for continuously casting strip |
JPH07103660A (en) * | 1993-10-08 | 1995-04-18 | Shinko Electric Co Ltd | Cold wall induction melting furnace |
JP2000264775A (en) * | 1999-03-23 | 2000-09-26 | Sumitomo Sitix Amagasaki:Kk | Electromagnetic induction casting apparatus |
CN2514005Y (en) * | 2001-12-11 | 2002-10-02 | 李碚 | Cold crucible vacuum smelting equipment with multifunctional operating system |
CN1287930C (en) * | 2004-08-11 | 2006-12-06 | 哈尔滨工业大学 | Water cooling electromagnetic copper type directional solidification method of titanium base alloy |
KR100564770B1 (en) * | 2004-08-18 | 2006-03-27 | 한국생산기술연구원 | apparatus for continuously casting an low electroconductive material by induction |
CN100368121C (en) * | 2005-09-02 | 2008-02-13 | 哈尔滨工业大学 | Directional freeze method for TiAl-based alloy plate |
CN1320972C (en) * | 2005-09-02 | 2007-06-13 | 哈尔滨工业大学 | Rectangular cold crucible system suitable for continuous fusion casting directional freeze |
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2007
- 2007-08-29 CN CNB2007100727143A patent/CN100460107C/en not_active Expired - Fee Related
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101603776B (en) * | 2009-05-08 | 2011-02-09 | 北京航空航天大学 | Induction melting cold crucible |
CN101885053A (en) * | 2010-06-24 | 2010-11-17 | 西北工业大学 | Strong pulse current orientated solidification grain ultra-fining method and device |
CN103691912A (en) * | 2013-12-19 | 2014-04-02 | 东北大学 | Gold base alloy casting blank melting and casting integrated device and utilization method thereof |
CN103691912B (en) * | 2013-12-19 | 2015-07-15 | 东北大学 | Gold base alloy casting blank melting and casting integrated device and utilization method thereof |
CN104209483A (en) * | 2014-09-28 | 2014-12-17 | 哈尔滨工业大学 | Melting and electromagnetic constraint shaping system capable of performing efficient electro-thermal conversion |
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