KR20150091727A - Ferro silicon molding apparatus - Google Patents

Abstract

The purpose of the present invention is to provide an apparatus to mold ferrosilicon capable of inserting most of ferrosilicon into a steel making process. To achieve this objective of the present invention, the apparatus to mold ferrosilicon capable of casting ferrosilicon used for a sub-material of a steel making process comprises: a distributor to uniformly distribute molten ferrosilicon after receiving the molten ferrosilicon through a water supply device; a chain device including a front sprocket and a rear sprocket, rotated by a driving device to an unlimited orbit; a plurality of mold sets continuously mounted on a chain device, and to accommodate molten ferrosilicon supplied through the distributor; a cooling device arranged on an upper surface of the chain device to cool the mold set and the ferrosilicon mounted inside the mold set; and a drying device arranged on a lower surface of the chain device to cool the mold set before the mold set enters the distributor. Moreover, ferrosilicon solidified inside the mold set is discharged from the front sprocket.

Description

[0001] Ferro silicon molding apparatus [0002]

The present invention relates to a ferrosilicon casting apparatus, and more particularly to a ferrosilicon casting apparatus for casting ferrosilicon suitable for a steelmaking process.

In general, ferrosilicon means a mixture of iron and silicon, and has various industrial applications, but its typical use is in the steelmaking process.

The steel contains various materials based on iron, and each of the materials is added in different ranges depending on the type of steel.

Since silicon is also used for improving the properties of steel and the silicon is introduced through ferrosilicon, the control of ferrosilicon content is also an important factor in the steelmaking process, and the ferrosilicon is produced in various ways.

Typically, there is a conventional method of manufacturing by mixing mild steel and silicon. The above method has an advantage that steel waste can be utilized, and the manufacturing method is relatively simple.

Also, there is a method of utilizing silicon in waste. For example, Laid-Open Patent Application No. 2012-0043216 discloses a method in which a mixed sludge is mixed with a silicon sludge, which is generated in large quantities in the process of manufacturing a semiconductor or a photovoltaic plate, After drying, water glass is compression molded using an adhesive to produce molded ferro silicon.

Ferrosilicon, on the other hand, may be a separate component due to its own characteristics. For example, Laid-Open Patent Application No. 2009-0130721 discloses that a silicon content of 50 wt% to 75 wt% in the total weight and a grain size of 0.1 mm to 16 mm is formed by a plurality of ferro silicon (Fe-Si) % And 5 wt.% To 10 wt.% Of a binder. The composition of the ferrous silicon briquette for raising the temperature of the molten metal is disclosed.

On the other hand, the ferro silicon used in the steelmaking process is melted through the melting furnace.

The melting of the ferrosilicon is completed, and the molten ferrosilicon is injected into the mold composed of a single frame to cast in the form of a single rectangular plate.

Before the steel making process is completed, the casting completed ferrosilicon flat plate is crushed by using an excavator or the like, and then the ferrosilicon filling process is completed by the steel making process.

The above method has disadvantages in that it is not produced as a piece having a certain size when the ferric silicon flat plate is crushed, and that the ferrosilicon powder is generated at the time of crushing.

In particular, ferrosilicon is known to have the highest efficiency in the range of a certain size when the steel making process is put into operation, and small pieces and powder can not be supplied to the process, resulting in loss of material and adversely affecting economic efficiency.

It is an object of the present invention to provide a ferrosilicon casting apparatus capable of putting most ferrosilicon into a steelmaking process.

In order to achieve the above object, the present invention provides a ferrosilicon casting apparatus for casting ferrosilicon used as a part of a steelmaking process, comprising: a distributor for distributing melted ferrosilicon through a hot water heater and distributing the same; A chain device including a front sprocket and a rear sprocket and rotated in an anisotropic orbit by a driving device; A plurality of metal seats successively seated on the chain device and receiving molten ferro silicon supplied through the distributor; A cooling device disposed on an upper surface of the chain device and cooling the ferrosilicon seated in the mold set and the mold set; And a drying device disposed on a lower surface of the chain device and cooling the mold set before entering the distributor, wherein the ferrosilicon solidified in the mold set is discharged from the front sprocket.

Preferably, the distributor is divided into a space by a partition wall, a communication hole is formed at a lower end of the partition wall, a guide portion and a guide hole are formed on a front surface of the distributor, And an emergency device for rotating the dispenser at a predetermined angle in an urgent situation is disposed on the lower surface of the distributor and the molten ferro silicon is introduced into the mold through the guide portion.

More preferably, the mold set is formed with a plurality of receiving holes having the same internal shape, and the guide holes are formed at the same positions as the number of the receiving holes in the width direction.

More preferably, the mold set is formed in a discharging device below the receiving hole, and the discharging device is operated by a full sprocket to discharge solidified ferro silicon located therein.

More preferably, the discharging device includes a discharging hole formed in the bottom of the receiving hole, a discharging rod seated in the discharging hole, a head formed on the top of the discharging rod, a spring connecting between the discharging rod and the mold set And when the load is not applied to the discharge rod, the head closes the lower portion of the seating hole by the action of the spring.

More preferably, a pressing portion is formed in the front sprocket, and the pressing portion presses the lower end of the discharging rod to discharge the solidified ferro silicon.

Preferably, the mold set includes an inner blocking wall for separating the receiving hole and an outer blocking wall formed outside the mold set, and an inclined surface is formed at an upper end of the blocking wall.

More preferably, the front outer blocking wall of the mold set includes a top guide for receiving a rear outer blocking wall of a neighboring mold set, and the top guide is formed with an inclined surface.

Preferably, the chain device includes a chain set engaging the front sprocket and the rear sprocket, the chain set comprising: a plurality of chain shafts; A roller rotatably coupled to an end of the chain shaft and meshing with the grooves of the front sprockets and the rear sprockets; A stationary plate coupled to a neighboring chain shaft; And a link coupled to an adjacent chain shaft, wherein the mold set is fixed to the fixing plate.

Preferably, the cooling device is characterized in that water is sprayed in the form of mist to cool the ferrosilicon and the mold set.

Preferably, the cooling device is also located on a lower surface of the chain device, and the mold set in which solidified ferrosilicon has been discharged is further cooled.

The ferrosilicon casting apparatus according to the present invention primarily dissolves ferrosilicon, continuously injects molten ferrosilicon into a plurality of mold sets rotated through a chain device, and automatically casts the ferrosilicon from the mold set to steel The present invention provides an apparatus for manufacturing a ferroelectric liquid crystal display device having an optimal size for inputting into a plasma display panel.

FIG. 1 is a configuration diagram of a casting apparatus for a ferrosilicon casting method according to the present invention,
Fig. 2 is a configuration diagram of the distributor shown in Fig. 1,
Fig. 3 is an operational state diagram of Fig. 2,
Fig. 4 is a configuration of the chain device shown in Fig. 1,
Fig. 5 is a configuration diagram of the chain set shown in Fig. 4,
Fig. 6 is a configuration diagram of the mold set shown in Fig. 1,
FIG. 7 is a layout diagram of the mold set shown in FIG. 6,
8 is a cross-sectional view of the discharge device shown in Fig. 6,
Fig. 9 is an operational state diagram of Fig. 8,
10 is a configuration diagram of the cooling device and the drying device shown in Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1, a ferrosilicone casting apparatus 100 according to the present invention includes a hot water heater 1, a distributor 10, a chain device 30, a mold set 50, a cooling device 80, (90).

The molten ferrosilicon is injected into the distributor (10). The molten ferrosilicon is injected into the distributor (10). The molten ferrosilicon is injected into the distributor (10) do.

As shown in FIG. 2, the distributor 10 has a rectangular cross-sectional shape and a space is formed therein. The molten ferro silicon introduced through the hot water heater 1 is supplied to a mold set 50 provided at a lower portion It plays a role.

In addition, the distributor 10 is provided with a separating wall 11 having a predetermined height at its bottom portion, and a plurality of communication holes 12 are formed below the separating wall 11.

The separating wall 11 serves to separate the inner space, and the molten ferro silicon introduced into the right side moves to the left through the communication hole 12 and moves to the left even if the amount of the molten silicon injected into the right space is changed. The molten ferro silicon remains constant.

A guiding portion 13 for injecting molten ferro silicon into the mold set 50 is formed on the left side of the distributor 10 and a plurality of guide holes 14 are formed in the guiding portion 13, 11) It is connected with the inner space.

Here, the guide holes 14 are formed by the number of the ferro silicon casting grooves formed in the mold set 50 described later.

Accordingly, the molten ferro silicon introduced into the right space moves to the left space through the communication hole 12, moves to the guide portion 13 through the guide hole 14, and finally reaches the mold set 50 Even if the amount of molten ferro silicon introduced into the hot water heater 1 is changed, the molten ferro silicon introduced through the guide portion 13 is relatively uniformly maintained.

As shown in FIG. 2, the surface of the distributor 10 through which the molten ferro silicon supplied by the hot water heater 1 is introduced is formed in a shape in which the injection surface 15 is cut, 15) are formed in an incision form so as to prevent the discharged product of molten ferrosilicon from being discharged to the outside.

The inside of the distributor 10 is made of refractory, and one side thereof is rotatably fixed with a rotary shaft 16 formed, but it is rotatable to the right by an emergency device 20 located at the lower end.

The emergency device 20 is constituted by a linear actuator and operates when molten ferro silicon is injected into the distributor 10 or there is a problem with the device located at the lower portion. As shown in FIG. 3, And serves to temporarily stop the molten ferro silicon contained in the inner space from being injected into the mold set 50 by rotating the distributor 10 to the right.

The chain device 30 is disposed at the lower end of the distributor 10. The chain device 30 includes a plurality of mold sets 50 coupled to the distributor 10, As shown in Fig.

4, the chain device 30 includes a plurality of front sprockets 31, a plurality of rear sprockets 35, a front sprocket 31, And a chain set 40 that is wound around a rear sprocket 35 and is driven by a driving device 39 for rotating the chain device 30, And serves to rotate the front sprocket 31 or the rear sprocket 35, and is formed entirely in an endless track.

5, the chain set 40 includes a chain shaft 41, a fixing plate 42 rotatably coupled to the chain shaft 41, rollers 43 fixed to the ends of the chain shaft 41 And a link 45 for connection with another chain shaft 41 located at the rear of the end of the chain shaft 41.

Meanwhile, since the fixing plate 42 is disposed in the width direction of the chain set 40, the chain shaft 41 may be configured to be located only on each side.

The fixing plate 42 is also fixed to another chain shaft 41 located rearward in the same manner as the link 45. That is, to the two chain shafts 41.

The rollers 43 are seated in the grooves 32 and 36 formed in the front sprocket 31 and the rear sprocket 35.

Therefore, in the chain set 40, when the front sprocket 31 and the rear sprocket 35 are rotated, the roller 43 is seated and moved in the grooves 32, 36 continuously.

On the other hand, the mold set 50 as shown in FIG. 6 is fixed to the fixing plate 42.

The mold set 50 is provided with a plurality of receiving holes 51 for receiving and cooling molten ferro silicon.

As shown in FIG. 6, the receiving holes 51 are connected in parallel with each other, and two rows are formed in total, but the number may be changed if necessary.

The number of parallel holes of the receiving holes 51 is equal to the number of the guide holes 14 and the interval of the guide holes 14 is equal to the side interval of the receiving holes 51, So that the molten ferro silicon discharged from the center of the receiving hole 51 can be injected into the center of the receiving hole 51.

The receiving hole 51 is divided through an inner blocking wall 52 and an upper end of the inner blocking wall 52 is formed with an inclined surface 52 that is inclined to a portion facing the receiving hole 51.

The inclined surface 52 guides the molten ferro silicon to the receiving hole 51 when the molten ferro silicon is injected into the inner blocking wall 52.

In addition, the four outer blocking walls 54 are also formed with inclined surfaces 55 inclined in the direction of the receiving holes 51, and the inclined surfaces 55 also serve to guide the molten ferro silicon to the receiving holes 51.

7, an upper guide 60 is formed on the outer block wall 54 located on the front side of the mold set 50. The upper guide 60 includes a mold set 50, and a sloped surface 61 is formed at an upper portion of the upper guide 60 in both directions.

The inclined surface 61 also functions to guide the molten ferro silicon introduced between the mold set 50 and the mold set 50 into the receiving hole 51.

In addition, in order to accommodate the change of posture when the mold set 50 is positioned on the sprockets 31, 35, a rear outer end blocking wall 54 located at the front is located below the upper guide 60 The lower end of the upper guide 60 may be curved so that the outer blocking wall 54 does not interfere with the upper guide 60.

8, a discharging device 70 is formed below the receiving hole 51 of the mold set 50. As shown in FIG.

The discharging device 70 includes a discharging hole 71 through which the discharging hole 71 is inserted and a discharging rod 72 through which the discharging hole 71 is inserted, a head 73 formed at the upper end of the discharging rod 72, And a spring 74 positioned between the mold set 50 and the discharge rod 72 and serving to cause the head 73 to close the discharge hole 71.

At this time, the lower end of the discharge rod 72 protrudes outside the mold set 50, and when the lower end of the discharge rod 72 is pressed, the head 73 protrudes to the upper end.

That is, after the molten ferro silicon is injected into the receiving hole 51, the molten ferro silicon is solidified, and when the discharging rod 72 is pressed, the solidified ferro silicon is separated from the receiving hole 51.

9 is coupled to the front sprocket 31. When the mold set 50 reaches the front sprocket 31, the discharge device 70 is rotated The coagulated ferrosilicon is released to the receiving hole 51 and then the coagulated ferrosilicon is discharged to the outside when the mold set 50 rotates more than 90 degrees in the full sprocket 31. [

On the other hand, at the top and bottom of the chain device 40, a cooling device 80 is located as shown in FIG.

The chiller 80 serves to cool the mold set 50 and is constructed in the form of a wattage mist. The water capacity is appropriately selected depending on the amount of molten ferro silicon to be supplied. Front and the lower end of the chain device 40, respectively.

The cooling device 80 evaporates when it comes into contact with the surface of the mold set 50 in such a manner that it is sprayed in the form of mist of water to cool the mold set 50. When the molten ferro silicon passes through the distributor 10, The chain device 40 may further include a drying device 90 and the drying device 90 may be provided in the form of a chain The mold set 50 located on the lower right side of the apparatus 40 and close to the distributor 10 is finally cooled.

The drying apparatus 90 is constituted by a blower and serves to reduce the temperature of the mold set 50 and to remove moisture on the surface of the mold set 50 by air cooling.

In the casting apparatus 100, molten ferrosilicon is transferred through the hot water heater 1 and then introduced into the distributor 10.

The molten ferro silicon is gradually introduced into the mold set 50 through the distributor 10.

In the mold set 50, the charged molten ferro silicon is contained in the receiving hole 51 and is gradually solidified.

The mold set 50 is then cooled by the chiller 80 located at the top while being transported by the chain device 50.

Thereafter, the discharging device 70 is operated by the pressing portion 33 located in the front sprocket 31 to discharge the solidified ferro silicon.

Thereafter, the mold set 50 is further cooled by the cooling device 80 located at the lower end.

Thereafter, it is finally cooled and dried by the drying device 90 and then moved to the lower end of the distributor 10.

The distributor 10 discharges only the molten ferro silicon to the extent that the molten ferro silicon is charged into the mold set 50 even if the molten ferro silicon is periodically injected into the distributor 10, So that ferro silicon can be cast.

Further, the mold set 50 can be manufactured using heat resistant steel, but it can be made of mild steel when controlling the amount of ferro silicon to be supplied. This is because even if the molten ferro silicon is injected into the mold set 50, the mold set 50 is sufficiently cooled by the cooling device 80 and the drying device 90 and is transferred to the lower end of the distributor 10 , Especially when mild steel is used, even if some constituents of the mold set 50 are eluted into the molten ferro silicon.

On the other hand, it is preferable that the solidified ferrosilicon is produced within the above-mentioned volume range, since it is suitable for the actual steel making process to produce a hexahedron or a cylinder having one side or a diameter of 30 mm or more and 70 mm or less.

That is, the space 51 formed in the mold set 50 can be used as a material for the steelmaking process without further processing.

While the present invention has been described with reference to a single chain device 40, the chain device 40 may be composed of a plurality of chain devices 40 as needed. When a plurality of the chain devices 40 are constructed, a plurality of mold sets 50 are also arranged in parallel. Therefore, the number of the mold sets 50 may be increased in conjunction with the number of the guide holes 14 of the distributor 10.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, And all of the various forms of embodiments that can be practiced without departing from the technical spirit.

1: Hot water heater 2: Support
10: distributor 11: separating wall
12: communication hole 13: guide portion
14: Guide hole 15: Insertion surface
16: rotating shaft 20: emergency device
30: chain device 31: full sprocket
32: groove 33:
35: After Sprocket 36: Home
39: drive device 40: chain set
41: chain shaft 42: fixed plate
43: roller 45: link
50: mold set 51: receiving hole
52: inner blocking wall 53: inclined surface
54: outer blocking wall 55: inclined surface
60: upper guide 61: inclined surface
70: discharge device 71: discharge hole
72: discharge rod 73: head
74: spring 80: cooling device
90: Drying apparatus 100: Casting apparatus

Claims (11)

A ferrosilicone casting apparatus for casting ferrosilicon used as a material for a steelmaking process,
A distributor for distributing the molten ferro silicon after being supplied through a hot water heater;
A chain device including a front sprocket and a rear sprocket and rotated in an anisotropic orbit by a driving device;
A plurality of metal seats successively seated on the chain device and receiving molten ferro silicon supplied through the distributor;
A cooling device disposed on an upper surface of the chain device and cooling the ferrosilicon seated in the mold set and the mold set; And
And a drying device disposed on a lower surface of the chain device and cooling the mold set before entering the distributor, wherein the ferrosilicon solidified in the mold set is discharged from the front sprocket.
The distributor according to claim 1, wherein the distributor is divided into a space by a dividing wall, a communication hole is formed at a lower end of the dividing wall, a guide portion and a guide hole are formed on a front surface of the distributor, Wherein an emergency device for rotating the distributor at a predetermined angle is disposed on a lower surface of the distributor and molten ferro silicon is introduced into the mold through the guide portion.
The ferrosilicon casting apparatus according to claim 2, wherein a plurality of receiving holes having the same internal shape are formed in the mold set, and the guide holes are formed at the same positions as the number of the receiving holes in the width direction.
The ferrosilicon casting apparatus according to claim 3, wherein a discharge hole is formed in a lower portion of the receiving hole of the mold set, and the discharging device operates by a full sprocket to discharge solidified ferro silicon located therein.
[5] The apparatus according to claim 4, wherein the discharging device comprises: a discharge hole formed in a lower portion of the receiving hole; a discharge rod seated in the discharge hole; a head formed on an upper end of the discharge rod; Wherein when the load is not applied to the discharge rod, the head closes the bottom of the seating hole by the action of the spring.
The ferrosilicon casting apparatus according to claim 5, wherein a pressurizing portion is formed on the front sprocket so that the pressing portion presses the lower end of the discharging rod to discharge solidified ferro silicon.
4. The ferrosilicon casting apparatus according to claim 3, wherein the mold set includes an inner blocking wall for separating the receiving hole and an outer blocking wall formed outside the mold set, and an inclined surface is formed at an upper end of the blocking wall. .
The ferrosilicon casting apparatus of claim 7, wherein the front outer blocking wall of the mold set includes a top guide for receiving a rear outer blocking wall of a neighboring mold set, and the top guide is formed with an inclined surface.
The chain according to claim 1, wherein the chain device comprises a chain set engaging the front sprocket and the rear sprocket, the chain set comprising:
A plurality of chain shafts;
A roller rotatably coupled to an end of the chain shaft and meshing with the grooves of the front sprockets and the rear sprockets;
A stationary plate coupled to a neighboring chain shaft; And
A link coupled to a neighboring chain axis,
Wherein the mold set is fixed to the fixed plate.
The ferrosilicon casting apparatus according to claim 1, wherein the cooling device cools the ferrosilicon and the mold set by spraying water in the form of mist.
11. The ferrosilicon casting apparatus according to claim 10, wherein the cooling device further cools the set of molds which are located on the lower surface of the chain device and in which the solidified ferrosilicon has been discharged.

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