Device for mixing molten metal in open-top mould

专利摘要:
An apparatus for stirring a molten metal in an open topped mould, in for example a continuous casting process, includes a series of electrical conductors which are positioned above the top of the mould and about the vertical axis thereof. Each of these conductors are connected to a different phase of a multi-phase alternating current supply, so that the currents flowing in the conductors will create a magnetic field which rotates about the vertical axis of the mould and penetrates down into the mould. Ferromagnetic pole pieces are associated with the conductors to provide a low reluctance flux path, which will reduce leakage of the magnetic field above the conductors and concentrate the field below the conductors where it penetrates down into the mould.
公开号:SU1301302A3
申请号:SU813308150
申请日:1981-06-04
公开日:1987-03-30
发明作者:Остин Мэлфорд Дэвид；Ричард Виттингтон Кит
申请人:Ти (Груп Сервисез) Лимитед (Фирма)；
IPC主号:

专利说明:

The invention is intended for electromagnetic stirring of a metal in a continuous casting mold.
The purpose of the invention is to increase the mixing efficiency.
FIG. 1 is a schematic diagram of the proposed device; in fig. 2 is a section A-A in FIG. 1, magnetic field diagram; in fig. 3 - structural diagram of the device; in fig. 4 - 6 - variants of the proposed device; in fig. 7 is a diagram of a four-phase alternating current source; in fig. 8 is a diagram of the connection of the excitation coils with conductors; in fig. 9 is a diagram of the mold; in fig. 10 is a section BB in FIG. 9; in fig. 11 - the same, option; in fig. 12 is the same as the embodiment.
The device contains a ring 1 and a ring 2, made of copper rod and connected at points 0.5, 1, rather than copper conductors 3. Excitation coils 4 are placed on conductors 3 and each of them is connected to one of the phases of the AC source. These elements form an electromagnetic transducer placed above the upper part of the mold 5 coaxially with it. The arrangement of the ring 1 does not prevent the supply of liquid metal 6 to the mold through a submersible cup 7.
Ring 2 may be located below ring 1 (Fig. 4), so that ring 2 encloses the upper edge of the mold 5, which itself can act as ring 2 (Fig. 5). In these cases, each wall of the mold 5 is connected to ring I by conductors 4, as shown in FIG. 6 In these embodiments, coils 4 are wound directly on conductors 3. It is possible to install pipes 8 for a cooler in sections 9 of conductors 3 adjacent to coils 4. In addition, the danger of overheating can be reduced by connecting coil 4 to conductor 3 by means of a ferromagnetic core 10 (Fig . eight).
The crystallizer 5 (Fig. 9) has water-cooled copper walls 11-14. The ring 1 is made with sides 15-18 connected to the walls 11-13 by copper connectors 19-21. As a result, a set is formed
five
0
five
0
five
0
five
0
five
.of three closed loops, the first of which is created by walls 1 and 12, connector 20, sides 16 and 15 of ring 1 and connector 19, the second wall 13, connector 21, side 17 and connector 20, and a third wall 14, connector 21 , side 18 and connector 19. A common pole 22 is mounted above the upper surface of the ring, and three other poles 23 - 25 are installed between ring 1 and the mold 5. Poles 23 - 25 are connected to pole 22 by ferromagnetic plates. 26 to 29 adjacent to the outer surfaces of the ring 1. Poles 23 to 25 can be mounted into a single plate with filling gaps between them with inserts 30 to 32 of non-magnetic material.
The efficiency of the device can be enhanced by symmetrically positioning the poles 33 - 36 between the ring 1 and the top of the mold 5. These poles can be connected to the ring 37, for which non-magnetic inserts 38 - 41 are installed between these poles (Fig. 11). The connecting plates 26 - 29 can be stratified layered, and their outer edges 42 are protected from splashes by plates 43 in the form of channels of non-magnetic material.
The device works as follows.
The passage of the supply current through the excitation coils 4 is induced in copper rods x 3 currents, the strength and direction of which depend on the position of the three-phase power supply cycle. The resulting currents appear in at least two of the aS, & b and fea sectors of ring 1 and the 1st, ae and
a f
it is ring 2. In the variant, when the current passes through the coil 4 connected to the first phase of the source is maximum, and the currents in the other coils are half the maximum, the current flows from point 1 to а ti is i and from points S and & and is equal to i / 2. As a result of the interaction of the currents, they will flow in loops m 5 pp-1 and 5e, and in the & or what the current will not be. The currents in areas a S and a o will be equal to each other and create magnetic fields, as shown in FIG. 2. Since the points in areas aS and a b are directed in the same direction, the magnetic fields formed inside the ring 1
practically destroy each other, however, the magnetic fields above and below the ring 1 amplify each other, the resulting magnetic field will lie almost parallel to the plane of the ring 1 above and below it. When the phases of the power supply change, the current distribution in the conductors changes, and the magnetic field rotates around an axis perpendicular to the plane of the ring 1. The rotating magnetic field induces a current in the molten metal inside the crystallizer 5, which in turn creates a magnetic field interacting with already created electromagnetic transducer. This causes the molten metal to rotate around the longitudinal axis of the mold.

权利要求:
Claims (3)
[1]
1. Device for mixing molten metal in crystalline
013024
an open top mash containing an electromagnet transducer located above the wok- crystallizer. It has a vertical axis, so that it is so that, in order to increase the mixing efficiency, the electromagnetic converter is made in the form of a set of electrical conductors from a non-ferromagnetic material and excitation coils and is supplied with a multi-phase AC source, while field coils mounted around
The 15 outer walls of the mold, and the other part of the conductors are connected to at least three closed loops connected by conductors with the excitation coils and connected through them to a multiphase AC source.
[2]
2. The device according to claim 1, characterized in that the closed
loops are made in the form of a ring.
[3]
3. A device according to claim 1, characterized in that the closed loops are made: in the form of a rectangle.
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Editor Y. Sereda
Compiled by V. Maltsev
Tehred; g Kadar Proofreader A, Zimokos
Order 1162/58 Circulation 741 Subscription
VNIIPI USSR State Committee
for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5
Production and printing company, Uzhgorod, st. Project, 4
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引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

DE185518C|

---

US1256705A|1916-06-02|1918-02-19|Triumph Electric Company|Induction-motor.|

---

GB705762A|1951-10-15|1954-03-17|Skf Svenska Kullagerfab Ab|Improvements relating to the continuous casting of metals|

---

FR1112845A|1953-09-21|1956-03-19|Casting molds|

---

BE541334A|1955-09-09|

---

US2861302A|1955-09-09|1958-11-25|Ver Leichtmetallwerke Gmbh|Apparatus for continuous casting|

---

US3610973A|1970-01-08|1971-10-05|Westinghouse Electric Corp|Vibration pickup device|

---

US3952791A|1974-01-08|1976-04-27|Nippon Steel Corporation|Method of continuous casting using linear magnetic field for core agitation|

---

GB1493110A|1974-02-15|1977-11-23|British Steel Corp|Moving molten ferrous masses|

---

JPS583075B2|1975-09-08|1983-01-19|Ishikawajima Harima Heavy Ind|

---

FR2338756B1|1976-01-20|1981-02-20|Creusot Loire|

---

FR2355392B1|1976-06-14|1981-01-30|Cem Comp Electro Mec|

---

FR2393632B1|1977-06-07|1980-01-18|Cem Comp Electro Mec|

---

JPS6056581B2|1978-09-11|1985-12-11|Nippon Kokan Kk|

---

JPS5554245A|1978-10-16|1980-04-21|Nippon Kokan Kk <Nkk>|Continuous casting method of steel|JP2528095B2|1986-03-19|1996-08-28|オリンパス光学工業株式会社|Welding monitoring equipment|

---

US4855982A|1987-05-18|1989-08-08|Eastman Kodak Company|Lens position-sensing apparatus for optical recording system|

---

US5246060A|1991-11-13|1993-09-21|Aluminum Company Of America|Process for ingot casting employing a magnetic field for reducing macrosegregation and associated apparatus and ingot|

---

DE19809631C1|1998-03-06|2000-03-30|Ks Kolbenschmidt Gmbh|Method and device for pouring a melt and castings produced therefrom|

---

KR100376504B1|1998-08-04|2004-12-14|주식회사 포스코|Continuous casting method and continuous casting apparatus used|

---

DE19843354C1|1998-09-22|2000-03-09|Ald Vacuum Techn Gmbh|Apparatus for oriented solidification of a metal melt cast into a mold shell comprises guide sheets in the liquid metal cooling bath for purposes of controlling the bath flow produced by magnetic fields|

---

JP3057233B1|1999-10-05|2000-06-26|名古屋大学長|Compression wave generator in conductive liquid|

---

US6988825B2|2002-07-03|2006-01-24|Bio/Data Corporation|Method and apparatus for using vertical magnetic stirring to produce turbulent and chaotic mixing in various states, without compromising components|

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EP2682753A1|2012-05-08|2014-01-08|Roche Diagniostics GmbH|Cartridge for Dispensing a Fluid Comprising a Reagent|

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AU2016374493A1|2015-12-15|2018-06-14|Grandfield Technology Pty Ltd|Ingot casting|

法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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GB8018372|1980-06-05|

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