JPH0724561A - Molten metal pouring trough - Google Patents

Abstract

PURPOSE:To provide a molten metal pouring trough, in which the yield is improved and the equipment cost can be reduced. CONSTITUTION:A chute 5 and the trough body 6 are separately arranged and a trough truck for shifting the trough body 6 in the longitudinal axial direction is arranged and a nozzle 23 for blowing gaseous nitrogen (N2 gas) 22 to the rear part of the molten metal 21 poured from the chute 5 into the trough body 6 is arranged at the center part of the rear of a pouring hole 5A for molten metal 21 of the chute 5 into the trough body 6. The molten metal 21 poured into the trough body 6 from the chute 5 is poured and cast into a rotary mold without remaining in the trough body 6 with the gaseous nitrogen 22 ejected from the nozzle 23 and therefore, the yield is improved. Further, as the trough body 6 has the constitution to shift by means of the trough truck at the time of casting, the equipment cost can be reduced in comparison with the equipment cost of the case of shifting the rotary mold with high accuracy of movement and further, the working accuracy can be improved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pouring trough for casting molten metal into a mold.

[0002]

2. Description of the Related Art An example of a conventional pouring trough will be described with reference to the perspective view of FIG. The pouring trough 41 guides the molten metal 43 poured from the triangular ladle 42 into the rotary mold 44 on the moving casting trolley (not shown), and includes the chute 45 into which the molten metal 43 is poured from the triangular ladle 42. , Molten metal poured into this shoot 45
A trough body 46 that guides 43 into the rotary mold 44 and a sport 47 at the tip are integrally welded. The shoot 45
Is the trough body with the molten metal 43 from the triangular ladle 42
It is for pouring into 47.

At the time of casting, the pouring trough 41 is inserted into the rotary mold 44, the rotary mold 44 is rotated, and the rotary mold 44 is moved in the direction of the arrow Y by the moving casting carriage, while the triangular ladle 42 is cast iron pipe. One or two melts 43 are poured into the chute 45, and are poured into the rotary mold 44 through the trough body 46 and the sport 47 to be cast.

[0004]

However, in the conventional pouring trough 41, the molten metal remains in the trough body 46, which causes the yield to be deteriorated. Further, in order to form a cast iron pipe having a predetermined pipe thickness and pipe length, the rotary mold 44 must be moved with high operation accuracy, and the equipment therefor must be expensive.

The present invention solves such problems, and an object of the present invention is to provide a pouring trough which can improve the yield and reduce the equipment cost.

[0006]

In order to achieve the above object, a pouring trough of the present invention separates a chute into which molten metal is poured and a trough body for guiding the molten metal poured into the chute into a rotary mold. A moving means for moving the trough body in the longitudinal direction thereof is provided, and a gas that does not react with the molten metal is poured from the chute into the trough body in the vicinity of the pouring port of the molten metal into the trough body of the chute. It is characterized in that a nozzle for spraying to the rear of the molten metal is provided.

[0007]

With this structure, the trough body is inserted into the rotary mold by the moving means, the rotary mold is rotated, and the molten metal is poured into the chute while pulling out the trough body from the state by the moving means. It is poured into the rotary mold through the trough body and cast. At this time, a gas that does not react with the molten metal is blown from the nozzle toward the rear of the molten metal poured from the chute into the trough body, and the molten metal is pushed out toward the rotary mold by the gas blown from the rear.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. 1 is a sectional side view of a main part of a pouring trough in one embodiment of the present invention, FIG. 2 is a configuration diagram of a casting facility using the pouring trough, and FIG. 3 is a view taken along the line AA of FIG. 4 (a) ~
(c) is a plan view, front view, and side view of the nozzle of FIG. 1.

The pouring trough 1 guides the molten metal 21 poured from the triangular ladle 2 into the rotary mold 4 on the moving casting trolley 3, and a chute 5 into which the molten metal 21 is poured from the triangular ladle 2. The molten metal 21 poured into this chute 5 is the rotary mold 4
It is composed of a trough main body 6 which is guided inward, and a trough truck 8 on which the trough main body 6 is placed and which moves on a rail 7 laid on a constant slope. During casting, the trough body 6 is moved by the trough truck 8 in the arrow X direction from the casting start position shown by the solid line to the casting end position shown by the two-dot chain line. The chute 5 is for pouring the molten metal 21 from the triangular ladle 2 into the trough body 6 with a force.

Further, molten metal for the trough body 6 of the chute 5
Nitrogen gas (N ₂ gas) 22 in the center of the back surface of spout 5A of 21
Melted from the chute 5 into the trough body 6 21
Nozzle 23 for spraying to the rear of is provided. Further, a nitrogen gas pipe 24 for supplying the nitrogen gas 22 to the nozzle 23 is laid along the back surface of the chute 5.

The nozzle 23 is formed in a box shape in which the front surface 23A is inclined forward, and is provided with a plurality of ejection ports 31 for ejecting the nitrogen gas 22 obliquely downward in a row in the lower part of the front surface 23A.
The rear surface 23B is provided with a connection port 32 to which the nitrogen gas pipe 24 is connected. Inside, a first conduit 33 for guiding the nitrogen gas 22 in the front-rear direction from the connection port 32 and both side surfaces 23C, 23C are penetrated, There are provided a second conduit 34 in which the first conduit 33 is opened, and a plurality of third conduits 35 for guiding the nitrogen gas 22 from the second conduit 34 to each ejection port 31. By this nozzle 23, the nitrogen gas 22 supplied from the nitrogen gas pipe 24 is guided from the connection port 32 to the second conduit 34 by the first conduit 33, and the nitrogen gas 22 is discharged from the through holes 23D, 23D of the both side surfaces 23C, 23C. Along with the sucked air, it is guided from the second conduit 34 to the ejection port 31 through the third conduit 35, and the ejection port 31
A laminar flow is generated by jetting from 31 diagonally downward.

In casting, the molten metal 21 is first conveyed from a melting plant (not shown) by the hot water ladle 11 and temporarily stored in the stationary ladle 12, and from the stationary ladle 12 approximately one or two cast iron pipes are provided. The molten metal 21 is transferred to the triangular ladle 2, the trough body 6 is inserted into the rotary mold 4 by the trough truck 8 to the casting start position, and the rotary mold 4 is rotated. From this state, while moving the trough body 6 from the trough truck 8 in the direction of the arrow X (while pulling out), the molten metal 21 for one or two cast iron pipes is poured from the triangular ladle 2 into the chute 5.
It is poured into the rotary mold 4 through the trough body 6 and cast. At this time, the nitrogen gas 22 ejected from the nozzle 23
However, from the rear of the molten metal 21 poured into the trough body 6, the molten metal 21 is sprayed from the rear side of the molten metal 21A into the trough body 6 and the amount of the cast iron pipe or two molten metal 21 is poured into the trough body 6. Without being left behind, it is poured and cast into the rotary mold 4.

When the casting is completed, the casting carriage 3 is moved in the direction of the arrow Y from the casting position indicated by the solid line to the cast iron pipe unloading position indicated by the chain double-dashed line, and the cast iron pipe is pulled out from the rotary mold 4 and the iron pipe unloading device is operated. It is carried out (not shown).

As described above, the nitrogen gas 22 ejected from the nozzle 23 pours the molten metal 21 poured into the trough body 6 into the rotary mold 4 without remaining in the trough body 6 and thereby a predetermined pipe is formed. A thick cast-iron pipe can be formed, and the yield can be improved. In addition, during casting, the trough body 6 is moved by the trough truck 8, and the equipment cost for moving the rotary mold 4 with high operation accuracy as in the conventional case because the trough body 6 is lightweight and has a small number of drive parts. Compared with, the equipment cost can be reduced and the operation accuracy can be improved.

[0015] In this embodiment, the use of the nitrogen gas 22, may be any gas which does not react with the molten metal, for example may be used such as air or argon gas (A _r gas). Further, although the nozzle 23 uses a nozzle having a plurality of jet ports 31, it is also possible to use a nozzle having a single jet port.

[0016]

As described above, according to the present invention, the gas that does not react with the molten metal from the nozzle is blown to the rear of the molten metal poured from the chute into the trough body, and the molten metal is rotated by the gas blown from the rear. By being extruded in the mold direction, the molten metal does not remain in the trough body, and the yield can be improved. Also,
By moving the trough body during casting, the number of drive parts is reduced, and the equipment cost can be reduced compared to the equipment cost when moving the rotary mold with good operation accuracy as in the past. Can be improved.

[Brief description of drawings]

FIG. 1 is a cross-sectional side view of essential parts of a pouring trough according to an embodiment of the present invention.

FIG. 2 is a configuration diagram of a casting facility using the pouring trough.

FIG. 3 is a view on arrow AA of FIG.

4 is a plan view, a front view, and a nozzle of the pouring trough shown in FIG.
It is a side view.

FIG. 5 is a perspective view of a conventional pouring trough.

[Explanation of symbols]

 1 pouring trough 2 triangular ladle 3 casting trolley 4 rotary mold 5 chute 6 trough body 7 rail 8 trough trolley 11 hot water ladle 12 stationary ladle 21 molten metal 22 nitrogen gas 23 nozzle 24 nitrogen gas pipe 31 spout

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Ayumi Kubo 2-16-1, Sakaemachi, Funabashi City, Chiba Stock Company Kubota Funabashi Plant (72) Inventor Hitoshi Hara, 2-16-1, Sakaemachi, Funabashi, Chiba Prefecture Stock company Kubota Funabashi factory

Claims (1)

[Claims] 1. A chute into which the molten metal is poured and a trough body for guiding the molten metal poured into the chute into a rotary mold are separately provided, and a moving means for moving the trough body in the longitudinal direction thereof is provided. , A gas that does not react with the molten metal near the pouring port of the molten metal into the trough body of the chute,
A pouring trough characterized by having a nozzle for spraying the molten metal poured from the chute into the trough body.