JP2004292941A - Apparatus for refining molten metal and method for refining molten metal using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an apparatus for refining a molten metal where impurities can efficiently be removed by jointly using chemical reaction by flux and physical action by inert gas, and to provide a method for refining a molten metal using the same. <P>SOLUTION: The apparatus 1 for refining a molten metal comprises: a gas supply pipe 16 of inert gas G; a rotary feeder 6 supplying a flux powder P to the gas supply pipe 16; a rotary shaft 32 having a communication passage 34 disposed therein so as to communicate with the gas supply pipe 16, and inserted into a molten metal M under the condition capable of rotating in one-way direction as well as normal and reverse directions; and a rotator 36 disposed on a top end of the rotary shaft 32 and including a discharge port 38 to discharge the inert gas G only or a mixture of the inert gas G and the flux powder P into the molten metal M. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

【００２４】
表１によれば、実施例では、不純物（非金属介在物）の数が当初のフラックス処理ステップ前の約７７分の１（約１．３％）に低減していた。特に、脱ガス処理ステップの前後では、３０分の１に激減していた。これは、フラックスによる化学的処理をした後、旋回流が生じない緩やかな正逆回転（正回転および逆回転）下による微細なＡｒガスの放出により、不純物が効率良く除去されたものである。
一方、比較例１では、上記と同じ脱ガス処理ステップのみを施したため、不純物は当初の約１４分の１（約７％）となるに留まった。
更に、比較例２では、実施例と同じフラックス処理ステップを行ったにも拘わらず、一方向の回転による脱ガス処理ステップを行ったため、不純物は当初の約１１分の１（約８．９％）に留まり、各例の中で最も多く残っていた。
加えて、表１に示すように、水素の含有量も、実施例が最も少なくなり、比較例２，１の順で多く残っていた。
以上のような実施例の結果によれば、本発明の金属溶湯の精製方法およびこれに用いた精製装置１の作用および効果が理解され裏付けられたことが判る。
【００２５】
図３は、異なる金属溶湯の精製装置１ａを示す外観図、図４は、係る精製装置１ａの垂直断面図である。
金属溶湯の精製装置１ａは、図３，４に示すように、上・下端に入口４５と出口４６とを有する不活性ガスＧのガス供給管路４４、その途中にフラックス粉末Ｐを供給するホッパ２およびスクリューフィーダ５０からなる粉末供給手段、前記同様の制御・回転部２０、回転シャフト３２、および回転体３６を備える。
図４に示すように、スクリューフィーダ５０は、水平向きの円筒形のケーシング５１内に、その軸方向に沿って螺旋形状の送給路５４を有するほぼ円柱形のスクリュウ軸５２を回転可能に内蔵している。
【００２６】
係るスクリュウ軸５２は、モータＭ３により回転可能とされ、上方のホッパ２の排出孔４からケーシング５１の途中に落下したフラックス粉末Ｐは、図４に示すように、回転するスクリュウ軸５２よってその送給路５４を先端５６側に送られる。尚、ホッパ２の外側には、フラックス粉末Ｐがコーン部付近で架橋現象を生じないよう、振動を与えるためのバイブレータ５が付設されている。
図４に示すように、スクリュウ軸５２の先端５６側に送られたフラックス粉末Ｐは、合流部４８からガス供給管路４４を不活性ガスＧと混合されつつ出口４６から制御・回転部２０に送られる。
【００２７】
そして、モータＭ２により一方向回転する回転シャフト３２の通気路３４および回転体３６の放出口３８を経て、フラックス粉末Ｐと不活性ガスとの混合物は、ルツボ４０内のアルミニウム溶湯（金属溶湯）Ｍ中に均一に放散される。
上記フラックス処理ステップの後は、前記スクリューフィーダ５０を停止し、不活性ガスＧのみを交互に正逆回転する回転体３６からアルミニウム溶湯Ｍ中に微細にして緩やかに放出することにより、脱ガス処理ステップを行うことができる。即ち、以上のような金属溶湯の精製装置１ａによっても、前記精製装置１と同様に前記精製方法を確実に行って金属溶湯を清浄化することができる。
【００２８】
本発明は、以上に説明した各形態および実施例に限定されるものではない。
例えば、前記フラックス処理ステップにおいて、前記回転体を正逆回転させたり、あるいは、前記脱ガス処理ステップにおいて、前記回転体を金属溶湯中に旋回流を生じないようにして一方向回転させても良い。
更に、不活性ガスには、Ａｒや窒素のほか、これらの混合ガスも含まれる。
また、回転シャフト３２や回転体３６を回転するモータＭ２などを含む制御・回転部２０は、ルツボ４０の真上に配置する形態に限らず、チェーンやギアなどの動力伝達手段を介することで、ルツボ４０の外側に配置しても良い。
更に、金属溶湯Ｍを保持するルツボは、耐火物などからなる円筒形の本体を含むものであれば、周囲にヒータまたは誘導コイルなどの加熱手段を巻き付けた溶解炉や保持炉を用いても良い。
尚、本発明の対象となる金属溶湯には、前記アルミニウムやその合金のほか、マグネシウムまたは銅あるいはこれらの何れかをベースとする合金も含まれる。
【００２９】
【発明の効果】
本発明の金属溶湯の精製装置（請求項１）によれば、回転体の一方向回転または正逆回転により不活性ガスとフラックスとの混合物を微細化しつつ金属溶湯中に均一に分散し、不純物とフラックスとの化学反応によって得られる生成物を浮上・除去するフラックス処理ステップと、上記回転体の正逆回転または一方向回転により不活性ガスのみを微細気泡化して金属溶湯中に分散せしめ、金属溶湯中の不純物や残ったフラックスを物理的に浮上・除去する脱ガス処理ステップと、を任意の順序によって行うなど、溶湯の特性や不純物の種類に応じて最適条件による精製方法を行うことができる。
また、請求項２の精製装置によれば、ホッパ中のフラックス粉末を定量ずつ切り出して、不活性ガスと混合しつつ前記回転シャフトおよび回転体を介して金属溶湯中に分散させることができる。しかも、処理すべき金属溶湯や不純物の量に応じて、所要量のフラックス粉末を間欠的または連続的に記不活性ガスのガス供給管路に確実に供給することができる。
【００３０】
一方、本発明の金属溶湯の精製方法（請求項３）によれば、回転体による一方向回転または正逆回転で例えば化学反応に時間が必要なフラックス処理ステップを先行して行い、金属溶湯中の不純物をフラックスと共に浮上・分離させた後、不活性ガスのみを正逆回転または一方向回転し且つ旋回流を生じないことより微細気泡化させて残った不純物やフラックスを確実に浮上・除去できる。従って、係る２つのステップを効果的に行うため、金属溶湯中の不純物を効率良く除去することが可能となる。
【図面の簡単な説明】
【図１】本発明の金属溶湯の精製装置を示す外観図。
【図２】図１の金属溶湯の精製装置を示す垂直断面図。
【図３】異なる形態の金属溶湯の精製装置を示す外観図。
【図４】図３の金属溶湯の精製装置を示す垂直断面図。
【符号の説明】
１，１ａ……金属溶湯の精製装置
２……………ホッパ（粉末供給手段）
６……………ロータリフィーダ（粉末供給手段）
１６，４４…ガス供給管路
３２…………回転シャフト
３４…………通気路
３６…………回転体
３８…………放出口
５０…………スクリューフィーダ（粉末供給手段）
Ｇ……………不活性ガス
Ｐ……………フラックス粉末
Ｍ……………アルミニウム溶湯（金属溶湯）[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an apparatus for purifying a molten metal and a purification method used for the apparatus.
The metal in the present specification includes, for example, any one of aluminum, magnesium, and copper, and an alloy based on one of them.
[0002]
[Prior art]
In order to remove impurities in the molten aluminum, an inert gas is blown into the molten aluminum through a nozzle, and the molten aluminum is agitated by a rotating body provided at the tip of the nozzle to refine the inert gas. 2. Description of the Related Art A rotary degassing device that discharges gas has been proposed (for example, see Patent Document 1).
Also, a flux using an inert gas as a carrier gas is blown into the molten aluminum through a lance, and the molten aluminum is stirred by a revolving body provided at the tip of the lance to discharge the flux while dispersing the molten flux. A revolving body for flux dispersion of an apparatus has also been proposed (for example, see Patent Document 2).
Further, the rotation of the rotating body inserted into the molten light metal causes the inert gas to become microbubbles and diffuses in the molten light metal, thereby diffusing the inert gas and generating a convection opposite to the swirling flow before the swirling flow occurs in the molten light metal. A method of purifying molten light metal to be made has also been proposed (for example, see Patent Document 3).
[0003]
[Patent Document 1]
JP-A-7-233425 (pages 1 to 5, FIGS. 1 to 4)
[Patent Document 2]
JP-A-63-183136 (pages 1 to 5, pages 1 to 3)
[Patent Document 3]
Japanese Patent Publication No. 7-122106 (pages 1 to 5; FIGS. 1 to 6)
[0004]
However, the rotary degassing apparatus disclosed in Patent Document 1 merely removes physical impurities using only an inert gas and cannot efficiently remove impurities in the molten aluminum. Further, according to the molten metal processing apparatus using the flux dispersion revolving body disclosed in Patent Document 2, it is possible to discharge the inert gas and the flux into the stirred aluminum molten metal while making the revolving body at the lance tip finer. However, due to the spiral flow generated in the molten aluminum due to the rotation of the revolving structure, the finely divided inert gas is not uniformly dispersed in the molten metal, and the vicinity of the molten liquid surface together with the flux along the spiral flow. There was a problem that would emerge.
[0005]
[Problems to be solved by the invention]
Further, according to the method for refining molten light metal of Patent Document 3, the inert gas is finely bubbled and diffused into the molten light metal by the rotation of the rotating body, and the swirling flow is generated even though the flux is not used. Before the rotation occurs, the rotating body is rotated forward and reverse to alternately rotate the rotating direction of the rotating body in the normal direction and the reverse direction. For this reason, the inert gas that has been made into fine bubbles efficiently rubs against the molten light metal, so that physical removal of impurities can be effectively performed. However, although this purification treatment method has a considerable effect as compared with the conventional one-way rotation treatment method, it depends on the treatment of only the inert gas. Efficient removal was not possible in time.
The present invention solves the problems in the conventional technology described above, and a metal melt that can efficiently remove impurities contained in the metal melt by using both a chemical reaction by flux and a physical action by an inert gas. It is an object of the present invention to provide a refining apparatus and a method for refining a molten metal using the same.
[0006]
[Means for Solving the Problems]
In order to solve the above problems, the present invention provides a step of dispersing a flux in a molten metal using an inert gas as a carrier gas to aggregate impurities, and finely dispersing and dispersing only an inert gas in the molten metal to remove impurities. The step of floating near the liquid surface of the molten metal is sequentially or simultaneously performed in parallel. That is, the apparatus for refining molten metal of the present invention (Claim 1) comprises a gas supply pipe for inert gas, powder supply means for feeding flux powder to the gas supply pipe, and a gas supply pipe. A rotating shaft having a communicating air passage therein and inserted into the molten metal and capable of rotating in one direction and forward and reverse; and a rotating shaft disposed at the tip of the rotating shaft and including only the inert gas or the inert gas. A rotating body having a discharge port for discharging a mixture of the active gas and the flux powder into the molten metal.
[0007]
According to this, the mixture of the inert gas and the flux of the carrier gas is finely dispersed by the unidirectional rotation or the forward / reverse rotation of the rotating body and uniformly dispersed in the molten metal, and the mixture is obtained by a chemical reaction between the impurities and the flux. A flux treatment step of floating / removing a product to be produced, and turning only the inert gas into fine bubbles by one-way rotation or forward / reverse rotation of the rotator to disperse it in the molten metal, thereby removing impurities and remaining flux in the molten metal. And a degassing step of physically floating and removing the Pt is performed in an arbitrary order, and a refining method under optimum conditions can be executed according to the characteristics of the molten metal and the type of impurities. In particular, when releasing only the inert gas into the molten metal while forming fine bubbles by a rotating body that rotates forward and backward, as described later, a gentle flow that does not generate a swirling flow due to rotation in the molten metal. By performing the degassing treatment in the state described above, it becomes possible to more effectively purify the molten metal.
Although the type of the flux is not particularly limited, for example, chlorides, fluorides, carbonates, lead sulfates, nitrates and the like of alkali and alkaline earth metals are used.
[0008]
Further, in the present invention, the powder supply means may include a hopper storing the flux powder, and a rotary feeder or a screw having one communicating with a lower end of the hopper and the other communicating with a gas supply pipe of the inert gas. And a feeder (claim 2).
According to this, the flux powder in the hopper can be cut out by a fixed amount and dispersed in the molten metal via the rotating shaft and the rotating body while being mixed with the inert gas as the carrier gas. Moreover, the required amount of flux powder can be intermittently or continuously supplied to the gas supply line of the inert gas according to the content of the molten metal or impurities to be treated. The rotary feeder has a pair of rotary plates that rotate relative to each other with a coaxial center and has a partially overlapping through-hole, so that the flux powder can be reliably cut out by a fixed amount. Further, the screw feeder can rotate a horizontal screw shaft provided with a spiral groove, and can continuously supply the flux powder in a horizontal direction along the groove of the screw shaft. Further, it is preferable that the hopper is provided with a vibrator for bridging (bridge) breaking so that the flux powder inside does not cause a bridging phenomenon near the outlet.
[0009]
On the other hand, a method for purifying a molten metal according to the present invention (claim 3) is a method for purifying a molten metal used in the refining device, wherein a rotating body inserted into the molten metal is rotated in one direction or forward and reverse. A flux treatment step of diffusing a mixture of a fine inert gas and a flux powder into the molten metal through the rotating body, and releasing only the inert gas from the rotating body into the molten metal; A degassing step of applying one-way rotation or forward / reverse rotation to the molten metal within a range in which no swirling flow occurs in the molten metal.
[0010]
According to this, for example, a flux treatment step that requires a long time for a chemical reaction is performed in advance by unidirectional rotation or forward / reverse rotation by a rotating body, and after floating and separating impurities in the molten metal together with the flux, the inert By using a rotating body that rotates forward or backward or unidirectionally in a range in which only the gas does not generate a swirling flow in the molten metal, it is possible to reliably float and remove impurities and flux remaining after being finely bubbled.
Therefore, since the above two steps are effectively performed, it is possible to efficiently remove impurities in the molten metal. In the forward and reverse rotation, the forward rotation and the reverse rotation are alternately performed at the same time.
[0011]
In addition, according to the present invention, the degassing step is performed simultaneously and in parallel only by the flux processing step, and no swirling flow is generated in the molten metal during which the rotating body inserted into the molten metal is used. It is also possible to include a method for purifying the molten metal, in which the metal is rotated in one direction or forward and reverse. In this case, while rotating the rotating body in one direction or forward and reverse so as not to generate a swirl flow in the molten metal, the mixture of the inert gas and the flux can be uniformly discharged into the molten metal while miniaturizing the mixture. It is possible to purify while simultaneously performing the chemical aggregation reaction by the flux and the floating action by the inert gas that has become fine bubbles. However, it is preferable to perform a degassing step in which only inert gas is blown for several minutes to about 10 minutes at the end.
The method for purifying a molten metal according to the present invention includes a step of forming the molten metal purified through the above steps into an ingot by continuous casting, or a step of casting the purified molten metal into a required mold to form a casting. It is also possible to provide a method for producing an ingot or casting that further comprises any of the steps.
[0012]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a preferred embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is an external view showing an apparatus 1 for refining molten metal according to one embodiment of the present invention, and FIG. 2 is a vertical sectional view of the apparatus 1 for refining molten metal.
As shown in FIGS. 1 and 2, the apparatus 1 for purifying molten metal includes a gas supply line 16 for an inert gas G such as nitrogen or argon, and a hopper for feeding the flux powder P to the gas supply line 16. Powder supply means comprising a rotary feeder 2 and a rotary feeder 6; a carbon rotary shaft 32 having a ventilation path 34 communicating with the supply pipe 16 therein and inserted into the molten aluminum (metal melt) M in the crucible 40; , Including.
[0013]
As shown by the dashed arrow in FIG. 2, the flux powder P stored in the hopper 2 from the upper inlet 3 is dropped into the casing 7 of the rotary feeder 6 from the discharge hole 4 at the lower end of the cone. In the casing 7, a coaxially rotatable rotating disk 8 and a fixed disk 10 are incorporated, and through holes 9, 11 are drilled at positions away from the center thereof. A belt 13 is stretched between a peripheral surface of the turntable 8 and a pulley 12 attached to a side of the casing 7, and the turntable 8 can be rotated by rotating a motor M <b> 1. The discharge hole 4 of the hopper 2 opens at a position away from the center of the turntable 8, and the flux powder P dropped on the turntable 8, as shown in FIG. When the disc and the through hole 11 of the disk 10 communicate with each other, the disc is cut into the mixing tank 14 from the drop port 15 by a predetermined amount and falls.
[0014]
As shown by the dashed arrow in FIG. 2, in the substantially conical mixing tank 14, the flux powder P falling from the upper inlet 15 and the side gas supply as shown by the dashed-dotted arrow in FIG. 2. The inert gas G supplied from the pipe 16 is mixed, and the mixture is supplied to the lower rotation / control unit 20 via the lower discharge hole 17 and the rotary joint 18. However, in a closed state where the through holes 9 and 11 of the rotary feeder 6 are not in communication, only the inert gas G passes through the mixing tank 14 and rotates and controls through the discharge hole 17 through the rotary joint 18. It is sent to the unit 20.
[0015]
As shown in FIG. 2, the rotation / control unit 20 includes a motor M2 that rotates the rotation shaft 32 and the like, and a control unit 22 such as an inverter that controls the rotation speed and rotation direction of the motor M2. . The rotation / control unit 20 includes three or more horizontal members 25 fixed to bearings 24 hanging down from the bottom surface, a plurality of nuts 26 individually fixed to the tips thereof, and bolts 27 individually screwed to each nut 26. , And is supported above the crucible 40. At the lower end of each bolt 27, a support board 28 mounted on the opening edge of the crucible 40 is attached. The motor M2 can rotate in one direction and alternately in a forward direction and a reverse direction.
[0016]
As shown in FIG. 2, the flux powder P and the inert gas G vertically penetrating through the rotation / control unit 20 pass through a hollow portion in the rotation shaft 29 including the joint portions 30 and 31, and rotate through carbon. The air is supplied to the ventilation path 34 in the inside 32.
As shown in FIGS. 1 and 2, a disk-shaped rotating body 36 made of carbon is disposed at the tip of the rotating shaft 32. The rotating body 36 branches from the lower end of the ventilation path 34 and faces horizontally. Are formed radially. Each discharge port 38 is individually opened near the center of a plurality of concave portions 37 provided symmetrically on the peripheral surface of the rotating body 36. The reason why the rotating shaft 32 and the rotating body 36 are made of carbon is to prevent erosion by the molten aluminum M.
[0017]
Next, a method for purifying a molten metal using the purifying apparatus 1 will be described with reference to FIG.
As shown by a dashed line arrow in FIG. 2, an inert gas G made of nitrogen or argon is supplied from the gas supply line 16 to the mixing tank 14. Further, as indicated by a broken arrow in FIG. 2, the flux powder P in the hopper 2 is dropped into the mixing tank 14 by a predetermined amount via the rotary feeder 6 to generate a mixture with the inert gas G. I do. As shown by the solid arrow in FIG. 2, the mixture passes through the rotation / control unit 20, passes through the air passage 34 in the rotating shaft 32 that rotates in one direction at about 300 rpm, and passes through the discharge port 38 of the rotating body 36. It is released into the molten aluminum M in the crucible 40 as fine bubbles. At this time, the flux powder P is released into the molten metal M together with fine bubbles of the inert gas G, and floats upward in the molten metal M while chemically reacting and aggregating with impurities contained therein. By performing such a flux treatment step for a certain period of time, impurities in the molten metal M can be separated and floated.
[0018]
Next, the rotation of the rotary disk 8 in the rotary feeder 6 is stopped and the through hole 9 and the through hole 11 of the disk 10 are closed so that they do not communicate with each other. Then, only the inert gas G from the gas supply pipe 16 passes through the mixing tank 14, the rotation / control unit 20, and the ventilation path 34 of the rotating shaft 32, and flows into the aluminum melt M from the discharge port 38 of the rotating body 36. Released as fine bubbles. At this time, the motor M2 is alternately rotated forward and backward at about 450 rpm alternately in the forward and reverse directions for about 9 seconds, and the rotating body 36 is similarly rotated forward and backward. In addition, the timing for switching between the forward rotation and the reverse rotation is before a spiral swirling flow is generated in the molten metal M due to the rotation of the rotating body 36.
[0019]
That is, in a state in which the molten metal M is slowly stirred while rotating with the rotation of the rotating body 36, the inert gas G that has been turned into fine bubbles gradually floats in the molten metal M while remaining impurities and flux powder. P is physically blown up near the liquid level of the molten metal M to be removed. By performing such a degassing step for about 10 minutes, a clean aluminum melt M from which impurities (non-metallic inclusions) have been removed can be reliably obtained.
When the high-speed rotation that generates the above-mentioned swirling flow is performed, the aluminum melt M itself co-rotates with the spiral swirling flow accompanying the rotation of the rotating body 36, so that the inert gas G is uniformly dispersed and floated. It becomes difficult to work. After each of the above steps, a step of forming the obtained clean aluminum melt M into an ingot by known semi-continuous casting or a step of casting it into a predetermined mold to form a casting may be performed.
[0020]
【Example】
Here, specific examples of the purification method of the present invention will be described.
Three sets of JIS: AC2B (Al-Cu) aluminum alloys were prepared at a ratio of new lump: cutting powder of 5: 3, 400 kg each, and these were melted at 730 ° C. to obtain individual molten aluminum M. Was poured into a crucible 40 similar to that described above. In addition, the said swarf is a recycled material obtained by cutting the offcuts in the ingot of the aluminum alloy. The refining apparatus 1 is individually set in the three crucibles 40. As shown in Table 1, the flux powder P and the Ar gas (inert gas) are placed in one crucible 40 while rotating the rotating body 36 in one direction at 300 rpm. After a flux treatment step of continuously discharging the mixture with G into the molten metal M for 6 minutes, only the Ar gas G is alternately rotated at 450 rpm in forward and reverse rotations of the rotating body 36 for 8.8 seconds. A degassing step of discharging into the molten metal M while rotating was performed for 10 minutes.
The method and the aluminum melt M obtained at the beginning, during, and at the end thereof were used as examples.
[0021]
The supply amount of Ar gas in the flux treatment step was 15 liters / minute, the supply amount of flux was 90 g / minute (addition ratio to molten metal: 0.13 wt%), and the supply amount of Ar gas in the degassing step was 18 liters / minute. Met. The time required to switch the rotation direction of the rotating body 36 between the forward direction and the reverse direction was about 0.8 seconds.
Further, as shown in Table 1, another crucible 40 was subjected to only the same degassing treatment as described above. This method and the aluminum melt M obtained at the beginning, during, and at the end thereof were used as Comparative Example 1.
Furthermore, as shown in Table 1, after the remaining crucible 40 was subjected to the same flux treatment as described above, only the degassing treatment for rotating the rotating body 36 in one direction was performed for 10 minutes. Such a method and the aluminum melt M obtained at the beginning, during, and at the end thereof were used as Comparative Example 2.
[0022]
As shown in Table 1, the aluminum melt M obtained at the beginning, middle and at the end of each example is individually cast into a plate-shaped cast piece of 240 mm × 36 mm × 6 mm, and the cast piece is set to a width (short width). ) Was cut at 25 places along the direction, and the number of nonmetallic inclusions as impurities in 50 exposed (pieces) cut surfaces was visually measured. In addition, visually, impurities of approximately 100 μm or more can be recognized.
For each example, the total number of impurities at the time of each measurement and the average number (K value) of each cut surface were measured, and the results are shown in Table 1.
Furthermore, the content of hydrogen gas was measured by the Lansley method for the slabs of the above examples. The results are also shown in Table 1.
[0023]
[Table 1]

[0024]
According to Table 1, in the example, the number of impurities (non-metallic inclusions) was reduced to about 1/77 (about 1.3%) before the initial flux treatment step. In particular, before and after the degassing step, it was drastically reduced to 1/30. This is because impurities are efficiently removed by fine Ar gas release under gentle forward / reverse rotation (forward rotation and reverse rotation) in which no swirling flow occurs after chemical treatment with flux.
On the other hand, in Comparative Example 1, only the same degassing step as described above was performed, so that the amount of impurities was reduced to about 1/14 (about 7%) of the initial value.
Further, in Comparative Example 2, since the degassing process step was performed by rotating in one direction in spite of performing the same flux processing step as in the example, impurities were reduced to about 1/11 (about 8.9%). ) And remained the most in each case.
In addition, as shown in Table 1, the content of hydrogen was the lowest in the examples, and the content of hydrogen remained in the order of comparative examples 2 and 1.
According to the results of the examples described above, it is understood that the operation and effects of the method for purifying molten metal of the present invention and the purifying apparatus 1 used for the method are understood and supported.
[0025]
FIG. 3 is an external view showing a different apparatus 1a for refining molten metal, and FIG. 4 is a vertical sectional view of the apparatus 1a.
As shown in FIGS. 3 and 4, the metal melt refining apparatus 1a includes a gas supply pipe 44 for an inert gas G having an inlet 45 and an outlet 46 at upper and lower ends, and a hopper for supplying a flux powder P in the middle thereof. 2 and a powder supply means composed of a screw feeder 50, a control / rotation unit 20, a rotation shaft 32, and a rotation body 36 similar to those described above.
As shown in FIG. 4, the screw feeder 50 rotatably incorporates a substantially cylindrical screw shaft 52 having a helical feed passage 54 in a horizontally oriented cylindrical casing 51 along the axial direction thereof. are doing.
[0026]
The screw shaft 52 is rotatable by a motor M3, and the flux powder P dropped into the casing 51 from the discharge hole 4 of the upper hopper 2 is fed by the rotating screw shaft 52 as shown in FIG. The supply path 54 is sent to the tip 56 side. A vibrator 5 for applying vibration is provided outside the hopper 2 so that the flux powder P does not cause a bridging phenomenon near the cone portion.
As shown in FIG. 4, the flux powder P sent to the tip end 56 of the screw shaft 52 passes through the gas supply pipe 44 from the junction 48 to the control / rotation unit 20 from the outlet 46 while being mixed with the inert gas G. Sent.
[0027]
Then, the mixture of the flux powder P and the inert gas passes through the ventilation path 34 of the rotating shaft 32 and the discharge port 38 of the rotating body 36, which rotates in one direction by the motor M 2, and the mixture of the flux powder P and the inert gas Dispersed evenly inside.
After the flux treatment step, the screw feeder 50 is stopped, and only the inert gas G is finely and slowly discharged into the aluminum melt M from the rotating body 36 that alternately rotates forward and reverse, thereby degassing the gas. Steps can be performed. That is, even with the above-described apparatus 1a for refining a molten metal, the refining method can be surely performed to clean the molten metal similarly to the refining apparatus 1.
[0028]
The present invention is not limited to the embodiments and examples described above.
For example, in the flux processing step, the rotating body may be rotated forward or backward, or in the degassing processing step, the rotating body may be rotated in one direction so as not to generate a swirling flow in the molten metal. .
Further, the inert gas includes not only Ar and nitrogen but also a mixed gas thereof.
In addition, the control / rotation unit 20 including the motor M2 that rotates the rotating shaft 32 and the rotating body 36 is not limited to the form disposed directly above the crucible 40, but may be provided via a power transmission unit such as a chain or a gear. It may be arranged outside the crucible 40.
Furthermore, as long as the crucible holding the molten metal M includes a cylindrical main body made of a refractory or the like, a melting furnace or a holding furnace around which heating means such as a heater or an induction coil is wound may be used. .
In addition, the molten metal which is an object of the present invention includes magnesium or copper or an alloy based on any of these in addition to the aluminum and its alloy.
[0029]
【The invention's effect】
According to the apparatus for refining molten metal of the present invention (claim 1), the mixture of the inert gas and the flux is uniformly dispersed in the molten metal while the mixture of the inert gas and the flux is refined by unidirectional rotation or forward / reverse rotation of the rotating body. A flux treatment step of floating / removing a product obtained by a chemical reaction between the inert gas and the flux, and turning only the inert gas into fine bubbles by the forward / reverse rotation or unidirectional rotation of the rotating body to disperse in the molten metal; The degassing step of physically floating and removing impurities and remaining flux in the molten metal can be performed in an arbitrary order, and the purification method can be performed under optimum conditions according to the characteristics of the molten metal and the type of impurities. .
Further, according to the refining device of the present invention, the flux powder in the hopper can be cut out by a fixed amount and dispersed in the molten metal via the rotating shaft and the rotating body while being mixed with the inert gas. In addition, a required amount of flux powder can be intermittently or continuously supplied to the gas supply line of the inert gas depending on the amounts of the molten metal and impurities to be treated.
[0030]
On the other hand, according to the method for purifying a molten metal of the present invention (claim 3), a flux treatment step that requires a long time for a chemical reaction is performed in advance in a one-way rotation or a forward / reverse rotation by a rotating body, for example. After floating and separating the impurities together with the flux, only the inert gas is rotated forward or backward or in one direction and does not generate a swirling flow, so that fine bubbles are formed and the remaining impurities and flux can be reliably floated and removed. . Therefore, since these two steps are effectively performed, impurities in the molten metal can be efficiently removed.
[Brief description of the drawings]
FIG. 1 is an external view showing an apparatus for purifying molten metal of the present invention.
FIG. 2 is a vertical sectional view showing the apparatus for purifying the molten metal of FIG.
FIG. 3 is an external view showing a refiner for refining a molten metal in a different form.
FIG. 4 is a vertical sectional view showing the apparatus for purifying the molten metal of FIG. 3;
[Explanation of symbols]
1, 1a: Metal melt refining device 2 ... Hopper (powder supply means)
6 Rotary feeder (powder supply means)
16, 44 gas supply line 32 rotating shaft 34 air passage 36 rotating body 38 discharge port 50 screw feeder (powder supply means)
G: inert gas P: flux powder M: molten aluminum (molten metal)

Claims (3)

A gas supply line for an inert gas;
Powder supply means for supplying flux powder to the gas supply pipe,
A rotary shaft internally provided with a gas passage communicating with the gas supply pipe and inserted into the molten metal, and capable of one-way rotation and forward and reverse rotation;
A rotating body disposed at the tip of the rotating shaft and having a discharge port for discharging only the inert gas or a mixture of the inert gas and the flux powder into the molten metal,
An apparatus for refining molten metal, comprising: The powder supply means includes a hopper storing the flux powder, and a rotary feeder or a screw feeder, one of which communicates with a lower end of the hopper and the other of which communicates with a gas supply pipe of the inert gas.
The apparatus for purifying a molten metal according to claim 1, wherein: A purification method used for the purification apparatus according to claim 1 or 2,
A flux processing step of rotating the rotating body inserted into the molten metal in one direction or forward / reverse rotation, and diffusing a mixture of fine inert gas and flux powder through the rotating body into the molten metal,
A degassing process in which only an inert gas is released from the rotating body into the molten metal, and one-way rotation or forward / reverse rotation of the rotating body is applied to the molten metal within a range in which no swirling flow occurs in the molten metal. Steps and
A method for purifying a molten metal, comprising:

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