JPH05228616A - Casting trough for metal or alloy ingot - Google Patents

Abstract

PURPOSE:To suppress the generation of oxide and to prevent the sticking of the oxide in weir by preventing the entrapment of the air at the time of pumping up molten metal for metal or alloy ingot. CONSTITUTION:A casting trough assembly for metal or alloy ingot is composed of an alloy adjusting furnace 1, the pump having a discharging pipe 29 provided in the furnace 1, a mold 9 and the casting trough 10 from the discharging pipe 29 to the mold 9. Then the casting trough 10 bends the base part side upward to form a returning hole at the upper position, and at the tip side 20, the weir 21 for staying basin and a parting wall 27 are provided to form molten metal staying chamber 23 on the bottom part 22 and a discharging hole 30 at the tip part of the discharging pipe 29 is opened into the molten metal 31 in the molten metal staying chamber 23, and a vertical rotational shaft 32 is provided in the vicinity of the discharging pipe 29. The inside and the outside of the weir 21 for staying basin are formed as an inside circular surface 24 and an outside circular surface 25 becoming gradually higher and gradually lower and the top part of the weir 21 for staying basin is made to be acute edge 26.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a casting trough for a metal or alloy ingot.

[0002]

2. Description of the Related Art In the publicly known Japanese Patent Application Laid-Open No. 48-100316, as shown in FIG. 1, an electrolytic zinc melting furnace a,
Distillation zinc melting furnace b, pumps c and d, gutters e and f, alloy metal charging machine g, stirrer h, blending furnace i, muffle furnace j, pump k, casting trough n , Turntable m, mold r, stock conveyor t, and ingot take-out device s. Of the above, the casting trough n is a mere trough, as shown in the plan view of FIG. 2 and the vertical sectional view of FIG. 3 (see FIGS. 11 and 12 of the publication).

[0003]

Since the casting trough n of the above-mentioned known device is a mere trough, the molten metal discharged from the discharge port u of the pump k flows down at a stroke according to the gradient of the casting trough n. is there. In such a structure, air is entrained everywhere and an oxide residue is generated.
In order to reduce the generation of the oxide residue, it is advisable to form a molten metal reservoir chamber and carry out the tip opening of the discharge pipe provided in the furnace in hot water. However, if a weir is provided to form the molten metal storage chamber, another problem of deposit of residue on the top of the weir occurs, and this point also needs to be solved.

[0004]

Therefore, according to the present invention, there is provided a compounding and mixing furnace 1 and a pump 4 having a discharge pipe 29 provided in the furnace 1.
And a casting mold 10 and a casting trough 10 extending from the discharge pipe 29 to the casting mold 9. The casting trough 10 is formed by bending a base side 18 upward to form a return port 19 at an upper position,
At 0, a weir 21 and a partition wall 27 are provided to form a molten metal storage chamber 23 on the bottom portion 22, and the tip discharge port 3 of the discharge pipe 29 is formed.
0 is an opening in the molten metal 31 in the molten metal reservoir chamber 23, and a casting trough for a metal or alloy ingot provided with a vertical rotation shaft 32 in the vicinity of the discharge pipe 29, and the molten metal reservoir weir 21. The inner and outer sides are formed with an inner arc surface 24 and an outer arc surface 25 that gradually become higher and lower, and the top of the weir 21 for the pool is a casting trough for a metal or alloy ingot with a pointed end 26. It is a thing.

[0005]

An embodiment of the present invention will be described with reference to the drawings.
A reference numeral 1 denotes a blending metallurgical furnace (hereinafter simply referred to as a furnace), which is a separately provided electrolytic zinc melting furnace a as known (see FIG. 1).
Molten zinc ingot is injected from a distillation zinc melting furnace b through a pump and a gutter, and aluminum, antimony,
This is a furnace in which a desired amount of an alloying metal such as cadmium or misch metal is supplied from an alloying metal charging machine to form mixed gold. That is, not only the alloying metal but also the bare metal can be used. Since the present invention has the other points, the furnace can be implemented with only one furnace, but the embodiment illustrates a state in which three furnaces are provided. Reference numeral 2 is a furnace having the same structure as the furnace 1, and 3 is also a furnace having the same structure as the furnace 1. Reference numeral 4 is a pump for pumping provided in the above 1, 5 is a pump provided in the furnace 2, and 6 is a pump provided in the furnace 3.

Reference numeral 7 is a turntable for producing the ingot of the zinc metal or the mixed metal, which is intermittently rotated by a motor (not shown) about a central axis 8. About 16 molds 9 are radially arranged on the turntable 7, and the turntable 7 is intermittently rotated by the space between the molds 9. In the mold 9, casting is performed at a predetermined position, next is residue removal, the next 4 frames are heating, the next 2 frames are air cooling, the next 2 frames are water spray, and the next frame is water spraying. Is cooling, the next is shower, the next is die cutting, and the next three pieces are preheating.

The furnace 1 is provided with a casting trough 10 for flowing the molten metal pumped up by the pump 4 to the casting mold 9 located at the casting position. The tip injection part 11 of the casting trough 10 is provided with a vertically moving device 12 having an arbitrary structure so as to vertically move. Reference numeral 13 is a casting trough for pouring the mixed gold drawn up by the pump 5 of the furnace 2 into the casting mold 9 at the casting position. As described above, the tip injection part 11 of the casting trough 10 is moved upward by the vertical movement device 12. Then, the tip end injection portion 14 is moved downward by the vertical movement device 15 to inject the mixed gold with another alloy mixing ratio into the mold 9 at the casting position. Reference numeral 16 is a casting trough for pouring the mixed gold drawn up by the pump 6 of the furnace 3 into the casting mold 9 at the casting position. As described above, the tip injection portion 11 of the casting trough 10 and the tip injection portion of the casting trough 13 are poured. 14 is a vertical movement device 12,
When it is moved upward by 15, the tip injection portion 17 is alternately moved downward by the vertical movement device 18 to inject the mixed gold of another alloy mixing ratio into the mold 9 at the casting position (it should be noted that the vertical movement is performed vertically). When using a hydraulic cylinder in the device, the downward movement may be performed by the weight of the casting trough). Reference numeral 19 is a stock conveyor that conveys the die-cut ingot to a desired position.

Thus, the casting troughs 10, 13, 16
Are formed as shown in FIG. That is, the base side 35 is bent upward at an angle of about 45 ° to return to the upper position.
6 is formed, and a weir 21 for the pool is provided on the tip side 20 to form a molten pool 23 on the bottom 22 of the casting trough. An inner inclined surface 24 and an outer inclined surface 25 are formed so that the front side and the rear side of the basin for weir 21 gradually become higher and lower, and the top of the weir for basin 21 has a sharp end 26. Reference numeral 27 is a partition wall whose lower end 28 faces the molten metal storage chamber 23. Each of the pumps 4, 5 and 6 is provided with a discharge pipe 29, and a tip discharge port 30 of the discharge pipe 29 opens in the molten metal 31 in the molten metal reservoir chamber 23. The casting troughs 10, 13, 16 are vertically moved by a cylinder. Reference numeral 32 denotes its vertical rotation shaft, and the tip discharge port 30 is located near the shaft 32. Reference numeral 33 is a spout of the casting troughs 10, 13 and 16 and opens into the molten metal 31 of the mold 9 like the tip discharge port 30.

[0009]

[Operation] Next, the operation will be described. 1 due to the nature of the factory
... or several furnaces 1, 2, ... Are arranged, and each of the furnaces 1, 2, ... Is filled with a molten metal of zinc ingot or mixed gold having a different alloy component, heated, and alternately used. Furnace 1
The operation when only the machine is used, for example, when an ingot of zinc bullion is ordered, the furnace 1
Other than that is unnecessary, the vertical moving device 15 of the furnace 2 and the vertical moving device 18 of the furnace 3 are actuated to move both the casting trough 13 and the casting trough 16 upward about the shaft 32. Although it is in an electrically heated state, the molten alloy is prevented from flowing out, and only the tip injection part 11 of the casting trough 10 is moved downward by the vertical movement device 12 of the furnace 1 to face the casting mold 9 at the casting position. When the molten zinc ingot in the furnace 1 is pumped up by operating the pump 4, the discharge pipe 29 rises and is supplied into the molten metal reservoir chamber 23 from the tip discharge port 30 of the discharge pipe 29.

In this case, the casting trough 10 has its base portion 35
Is bent upward at an angle of about 45 ° to form a return port 36 at the upper position, and a tip 21 is provided with a weir 21 for the pool, and a molten pool chamber 23 is provided on the bottom 22 of the casting trough 10. Since it is formed, the molten metal 31 supplied from the tip discharge port 30 of the discharge pipe 29 is poured into the accumulated molten metal 31 as shown in FIG. 5, so that air is not entrained. Therefore, the generation of residue (oxide) is small. The slightly generated residue is blocked by the partition wall 27, and only the purified water passes under the partition wall 27, is guided by the inner inclined surface 24 and rises, and overflows beyond the pool reservoir weir 21. Although flowing, the front side and the rear side of the basin for weir 21 are formed with an inner inclined surface 24 and an outer sloping surface 25 that gradually become higher and lower, and the top of the weir 21 for basin has a sharp end 26. Therefore, the flow of molten metal is smooth and undisturbed, and there is little generation of residue in this portion.

In addition, since the top of the weir 21 for boiling water has a pointed end 26, almost no foreign matter is attached to the pointed tip 26, and it has an effect that does not change for a long time.
When the top of is made thick as shown in FIG. 6, the oxide 34 adheres and the oxide 34 grows gradually, which causes turbulence.) It should be noted that an ingot is created through a predetermined process by rotating the turntable 7 for manufacturing the ingot, die-cut at a die-cutting position, and transferred by a stock conveyor 17.

[0012]

Since the casting trough n of the above-mentioned known device is a simple trough, the molten metal discharged from the discharge port u of the pump k flows down at a stroke according to the gradient of the casting trough n. In such a structure, air is entrained everywhere and an oxide residue is generated. However, the present invention is directed to the compound metallurgical furnace 1 and the pump 4 having the discharge pipe 29 provided in the furnace 1.
And a casting mold 10 and a casting trough 10 extending from the discharge pipe 29 to the casting mold 9. The casting trough 10 is formed by bending a base side 18 upward to form a return port 19 at an upper position,
At 0, a weir 21 and a partition wall 27 are provided to form a molten metal storage chamber 23 on the bottom portion 22, and the tip discharge port 3 of the discharge pipe 29 is formed.
No. 0 is a casting trough for a metal or alloy ingot, which is opened in the molten metal 31 in the molten metal reservoir chamber 23 and provided with a vertical rotating shaft 32 near the discharge pipe 29.
The molten metal discharged from the discharge port is the molten metal 31 of the casting trough 10.
Since it is supplied inside, there is no entrainment of air, so there is little residue generation during supply, and since the vertical rotation shaft 32 is provided in the vicinity of the discharge pipe 29, the work of returning the molten metal 31 in the casting trough 10 is also smooth. Can be done.

Further, the inside arcuate surface 24 and the outside arcuate surface 2 in which the inside and the outside of the pool weir 21 gradually become higher and gradually lower.
5 and the summit 21 for forming a sump has a sharp end 26, so that the amount of oxide adhering to the sharp end 26 is small and the flow of the molten metal over the sump weir 21 is always smooth. Have.

[Brief description of drawings]

FIG. 1 is a known example diagram.

FIG. 2 is a plan view of a known cast gutter.

FIG. 3 is a side view of a known cast gutter.

FIG. 4 is a plan view of the present invention.

FIG. 5 is a vertical sectional side view of a main part of the present invention.

FIG. 6 is a vertical sectional side view other than the embodiment of the present invention.

[Explanation of symbols]

1, 2, 3 ... Blending metal furnace, 4, 5, 6 ... Pump, 7 ... Ingot manufacturing turntable, 8 ... Center axis, 9 ... Mold,
10, 13, 16 ... Cast gutter, 11 ... Tip injection part, 1
2, 14, 15 ... Vertical movement device, 17 ... Stock conveyor, 18 ... Base side, 19 ... Return port, 20 ... Tip side, 21
... Weir for pond, 22 ... Bottom of casting trough, 23 ... Molten chamber,
24 ... inner inclined surface, 25 ... outer inclined surface, 26 ... sharp end,
27 ... Partition wall, 28 ... Lower end, 29 ... Discharge pipe, 30 ... Tip discharge port, 31 ... Molten metal, 32 ... Vertical rotating shaft, 33 ... Spout, 34 ... Oxide, 35 ... Base side, 36 ... Return port ..

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Kiyotaka Tsuji No. 3 Asamu-cho, Omuta-shi, Fukuoka Prefecture Mitsui Kinzoku Kyushu Kiko Co., Ltd. (72) Nobuyuki Kurata No. 3 Asakuta-cho, Omuta-shi, Fukuoka 1 Mitsui Kinzoku Kyushu Kiko Co., Ltd. (72) Inventor Yoshio Sohama 1-1-1, Hikoshima Nishiyama-cho, Shimonoseki City, Yamaguchi Prefecture Hikoshima Smelting Co., Ltd. (72) Hideo Mokari 1 Hikoshima Nishiyama-cho, Shimonoseki City, Yamaguchi Prefecture 1-1-1 Hikoshima Smelting Co., Ltd. (72) Inventor Eiki Kajiwara 1-1-1 Hikoshima Nishiyama-cho, Shimonoseki City, Yamaguchi Prefecture 1-1-1 Hikoshima Smelting Co., Ltd. (72) Hiroko Matsuda Hikoshima Nishiyama, Shimonoseki City, Yamaguchi Prefecture 1-1-1 Town Hikoshima Smelting Co., Ltd.

Claims (2)

[Claims] 1. A casting / melting metal furnace 1, a pump 4 having a discharge pipe 29 provided in the furnace 1, a mold 9, and a casting gutter 10 extending from the discharge pipe 29 to the mold 9, The gutter 10 bends the base side 18 upward and returns it to the upper position 19
And forming a molten metal reservoir 21 and a partition wall 27 on the front end side 20 to form a molten metal reservoir chamber 23 on the bottom portion 22, and the distal end discharge port 30 of the discharge pipe 29 is located inside the molten metal reservoir chamber 23. Molten metal 31
A casting trough for a metal or alloy ingot, which is opened inside and provided with a vertical turning shaft 32 in the vicinity of the discharge pipe 29. 2. The inner side and the outer side of the weir 21 for hot water pool according to claim 1, are formed with an inner arc surface 24 and an outer arc surface 25 which gradually become higher and lower, and the top of the weir 21 for hot water pool is formed. A casting trough for a metal or alloy ingot with a sharp end 26.