KR102633123B1 - Ingot feeding apparatus for galvanizing zinc pot - Google Patents

Abstract

An ingot loading device for a hot-dip galvanizing bath is disclosed. The ingot insertion device of the hot-dip galvanizing bath is a device that automatically inserts the ingot into the ingot pot where the ingot is melted, and includes a transfer unit for transferring the ingot, a rail member installed between the transfer unit and the ingot pot, and a rail member. It is installed to be movable along and moves the ingot transferred from the transfer unit to the ingot pot position, a feeding unit installed between the transfer unit and the ingot pot to supply the ingot to the mobile trolley, and the ingot is located inside. It includes a rotating bracket that is rotatably installed on the mobile cart to insert the ingot into the ingot pot when rotated, and a driving unit that provides rotational driving force to the rotating bracket.

Description

Ingot feeding device for hot dip galvanizing bath {INGOT FEEDING APPARATUS FOR GALVANIZING ZINC POT}

The present invention relates to an ingot injection device for a hot-dip galvanizing bath that can stably insert an ingot into the hot-dip galvanizing bath without damaging the equipment.

Generally, in order to insert an ingot into a hot-dip galvanizing bath, a nipper unit is installed to clamp the ingot and guide it to the ingot pot.

In this way, the conventional ingot is put into the ingot pot by clamping the ingot using a nipper unit. In the process of putting the ingot, the ingot often falls inside the ingot pot due to a clamping error.

Accordingly, there is a problem in that damage to the ingot pot occurs due to the ingot falling, and equipment damage frequently occurs due to sloshing of the molten zinc due to the ingot falling inside the ingot pot.

One embodiment of the present invention is a molten zinc solution that allows stable input of an ingot without damaging the ingot pot during the process of inserting the ingot into the ingot pot and without causing sloshing of the molten zinc when inserting the ingot. The object is to provide an ingot insertion device for a plating bath.

One embodiment of the present invention is a device that automatically puts an ingot into an ingot pot where the ingot is melted, including a transfer unit for transferring the ingot, a rail member installed between the transfer unit and the ingot pot, and a transport unit along the rail member. A mobile cart that is movably installed and moves the ingot transferred from the transfer unit to the ingot pot position, a feeding unit that is installed between the transfer unit and the ingot pot and supplies the ingot to the mobile cart, and the ingot is located inside and moves. It includes a rotation bracket that is rotatably installed on the bogie to insert the ingot into the ingot pot when rotated, and a drive unit that provides rotational driving force to the rotation bracket.

The transfer unit may be a conveyor that transfers the ingot to the feeding unit location with a plurality of ingots seated on the top.

The feeding unit may include a supply roller that is rotatably installed between the transfer unit and the ingot pot and supplies the ingot to the mobile cart.

The mobile bogie has a first bogie body with a first drive wheel installed at the bottom to be movable along the rail member, and a supply space where ingots are supplied is formed between the first bogie body and a second drive at the bottom. It includes a second bogie body with wheels installed so that it can move along the rail member together with the first bogie body, and an internal roller that is rotatably installed between the first bogie body and the second bogie body to move the ingot. can do.

A rotation bracket may be rotatably installed between the first bogie body and the second bogie body.

The rotating bracket is installed on one side of the first and second bogie bodies to be rotatable on one side in the direction of the ingot pot, and has a bracket body inside which the ingot moved by the feeding unit is located, and a rotating bracket inside the bracket body. It can be installed to include a bracket roller that rotates and supports the ingot inside the bracket body.

One side of the rotating bracket protrudes to the outside of the mobile cart, and when rotating, one side is inclined toward the inside of the ingot pot, so that a plurality of ingots can be moved toward one side of the rotating bracket by their own weight.

The driving unit may include a wire member on one side connected to the rotation bracket to support the rotational state of the rotation bracket, and a drive motor connected to the other side of the wire member for controlling the rotation angle of the rotation bracket by winding the wire member.

According to one embodiment of the present invention, in a state in which a plurality of ingots are inserted into the inside of the rotating bracket, as the rotating bracket rotates at a certain angle, the ingots located at the outermost part are sequentially melted by contacting the molten zinc. A plurality of ingots can be automatically injected into the ingot pot at an appropriate speed corresponding to the melting speed.

According to one embodiment of the present invention, the ingot is input into the inside of the ingot pot at an appropriate speed, so the molten zinc does not slosh during the ingot input process, and damage to the ingot pot occurs due to the input of the ingot at an appropriate speed. You can prevent it from happening.

According to one embodiment of the present invention, a plurality of ingots are tilted while inserted into a rotating bracket and are inserted into the ingot pot, making it possible for various types of ingots to be appropriately introduced.

Figure 1 is a plan view schematically showing an ingot feeding device for a hot-dip galvanizing bath according to an embodiment of the present invention.
Figure 2 is a side view schematically showing an ingot inserted into the mobile cart of Figure 1.
Figure 3 is a side view schematically showing a mobile cart according to an embodiment of the present invention.
Figure 4 is a side view schematically showing a state in which the mobile cart according to an embodiment of the present invention has been moved to the ingot pot position.
Figure 5 is a side view schematically showing a state in which the rotation bracket is rotated on the mobile cart of Figure 4 and an ingot is put into the inside of an ingot pot.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. However, the present invention may be implemented in many different forms and is not limited to the embodiments described herein. In order to clearly explain the present invention in the drawings, parts not related to the description are omitted, and identical or similar components are given the same reference numerals throughout the specification.

The ingot input device of the hot dip galvanizing bath described below refers to a device that can input various ingots in the production process of hot dip galvanized products. This will be explained in detail below.

Figure 1 is a diagram schematically showing an ingot insertion device for a hot-dip galvanizing bath according to an embodiment of the present invention, and Figure 2 is a side view schematically showing an ingot inserted into the mobile cart of Figure 1. 3 is a side view schematically showing a mobile cart according to an embodiment of the present invention, and Figure 4 is a side view schematically showing a state in which the mobile cart according to an embodiment of the present invention has been moved to the ingot pot position. 5 is a side view schematically showing a state in which the rotating bracket is rotated on the mobile cart of FIG. 4 and the ingot is put into the inside of the ingot pot.

As shown in FIGS. 1 to 5, the ingot input device 100 of the hot-dip galvanizing bath according to an embodiment of the present invention automatically inputs the ingot into the ingot pot 60 where the ingot 11 is melted. It is a device that includes a transfer unit 10 for transferring the ingot 11, a rail member 32 installed between the transfer unit 10 and the ingot pot, and movable along the rail member 32. A mobile cart 30 moves the ingot 11 transferred from the transfer unit 10 to the position of the ingot pot 60, and is installed between the transfer unit 10 and the ingot pot 60 to transport the ingot 11. The feeding unit 20, which supplies to the mobile cart 30, and the ingot 11 are located inside and rotatably installed on the mobile cart, so that the ingot 11 is fed into the ingot pot 60 when rotated. It includes a bracket 40 and a driving unit 50 that provides rotational driving force to the rotating bracket 40.

The transfer unit 10 may be installed to transfer various types of ingots 11 for input into the ingot pot 60 for the production process of hot-dip galvanized products.

The transfer unit 10 may be installed to sequentially transfer a plurality of ingots 11 to the position of the rail member 32 and supply them to the mobile cart 30 that moves along the rail member 32.

This transfer unit 10 is installed to sequentially transfer a plurality of ingots 11 to the position of the rail member 32, and may be installed as a conveyor in this embodiment. However, in this embodiment, the transfer unit 10 is not necessarily limited to a conveyor, and can also be applied as a predetermined transfer machine that transfers the ingot along a rail.

The plurality of ingots 11 supplied by this transfer unit 10 may be supplied to the mobile cart 30 and transferred to the ingot pot 60. In this embodiment, the ingot pot 60 may be a hot-dip galvanizing bath filled with molten zinc. The plurality of ingots 11 transferred by the transfer unit 10 may be sequentially supplied to the mobile cart 30 by the feeding unit 20.

The feeding unit 20 is installed at a position between the transfer unit 10 and the ingot pot 60, and sequentially moves the plurality of ingots 11 supplied by the transfer unit 10 in the direction of the mobile cart 30. It may include a supply roller 21 that supplies.

The supply roller 21 is installed between the feeding unit 20 and the installation position of the mobile cart 30. A plurality of supply rollers 21 are installed to be rotatable by providing a predetermined driving force, and are installed inside the mobile cart 30. The ingot 11 can be installed to be positioned.

Meanwhile, as described above, the mobile cart 30 is installed to be movable along the rail member 32 while receiving the ingot 11 by the supply roller 21 constituting the feeding unit 20, It can be installed to move the ingot 11 to the ingot pot 60 position. Reference number 35 refers to the bogie drive motor.

To be more specific, the mobile cart 30 may include a first cart body 31 and a second cart body 33 that are movably installed along the rail member 32 and are connected to each other.

The first bogie body 31 may be installed to be movable along the rail member 32 by having a first driving wheel 31a installed at its lower portion.

The first bogie body 31 is connected to the second bogie body 33 and is installed to be movable together while seated on the rail member 32, and an ingot 11 is placed between the second bogie body 33. This supplied supply space can be formed.

The second bogie body 33 has a third drive wheel 33a installed at its lower portion and can be installed to be movable along the rail member 32.

This second bogie body 33 is formed between the first bogie body 31 and a supply space where the ingot 11 is supplied, and the supply space has an internal roller 35 for moving and seating the ingot 11. can be installed.

The internal roller 35 may be rotatably installed at a position between the first and second balance bodies 31 and 33 so that the ingot 11 transported through the supply roller 21 is moved and seated. The inner roller 35 may be installed at a certain height lower than the height of the supply roller 21 so that the ingot 11 moved from the supply roller 21 is moved and seated stably.

A rotation bracket 40 may be installed on the front side of the first bogie body 31 and the second bogie body 33 in the direction of the ingot pot 60.

The rotation bracket 40 is installed so that the ingot 11 supplied to the position between the first bogie body 31 and the second bogie body 33 is located inside, and the side is aligned with the first bogie body 31. It can be rotatably installed at a position between the second bogie bodies 33 by means of a hinge 41.

The hinge 41 may be installed at an asymmetrical position away from the center point of the rotation bracket 40 in the longitudinal direction and away from the molten metal surface of the ingot pot 60. Therefore, when the rotary bracket 40 is rotated, the molten zinc surface of the ingot pot 60 and the side surface of the rotary bracket 40 can be easily contacted.

In this way, the rotation bracket 40 is rotatably installed to sequentially transfer a plurality of ingots 11 inside the rotation bracket 40 to the ingot pot 60.

That is, when the mobile cart 30 is moved to the position of the ingot pot 60, the rotation bracket 40 is rotated in the direction of the ingot pot 60 by the driving operation of the drive unit 50, and during the rotation operation. Inside, a plurality of ingots may be sequentially moved by their own weight in the direction of the ingot pot 60.

Accordingly, the ingots 11, which are sequentially moved by their own weight in the omnidirectional direction in the rotation state of the rotation bracket 40, are sequentially melted and injected while the ingots 11 located on the inclined lower side of the rotation bracket 40 are sequentially melted. The operation can be performed smoothly.

For this purpose, the rotation bracket 40 is such that one side where the ingot 11 is inserted is open and the other side where the ingot 11 is in contact with the ingot pot 60 is closed, and the inclined side of the rotation bracket 40 is melted. The ingots 11 can be installed to be easily melted sequentially by being immersed in the zinc 61.

That is, the plurality of ingots 11 are sequentially melted in contact with molten zinc, starting from the ingot 11 located at the outermost position while inserted inside the rotating bracket 40, at the melting speed of the ingot 11. A plurality of ingots 11 can be automatically introduced into the ingot pot 60. Accordingly, the ingot 11 is input into the inside of the ingot pot 60 at an appropriate speed, so that the molten zinc does not slosh around during the input process of the ingot 11, but by inputting the ingot 11 at an appropriate speed. It is also possible to prevent damage to the ingot pot 60 from occurring.

Meanwhile, the tilted rotation operation of the rotation bracket 40 may be achieved by driving the driving unit 50.

This driving unit 50 has a wire member 51 on one side connected to the rotation bracket 40 to support the rotation state of the rotation bracket 40, and a wire member 51 connected to the other side of the wire member 51. It may include a drive motor 53 that provides driving force for winding.

One side of the wire member 51 may be connected to one side of the rotation bracket 40, that is, the side opposite to the side in contact with the molten zinc of the ingot pot 60.

This wire member 51 may be installed extended in the direction of the drive motor 53 while being supported by the pulley member 52.

The drive motor 53 may be installed to properly adjust the rotation angle of the rotation bracket 40 by winding or unwinding the wire member 51 around the outside of the drive shaft by rotating the drive shaft.

As described above, the ingot insertion device 100 of the hot-dip galvanizing bath of the present embodiment includes a plurality of ingots 11 inserted into the rotary bracket 40, starting from the ingot 11 located at the outermost position. As the zinc melts sequentially in contact with the molten zinc, a plurality of ingots 11 can be automatically injected into the ingot pot 60 according to the melting speed of the ingots 11.

Accordingly, the ingot 11 is input into the inside of the ingot pot 60 at an appropriate speed, so that the molten zinc does not slosh around during the input process of the ingot 11, but by inputting the ingot 11 at an appropriate speed. Damage to the ingot pot 60 can be prevented.

In addition, since a plurality of ingots 11 are tilted while inserted into the rotating bracket 40 and inserted into the ingot pot 60, it is possible to properly insert various types of ingots.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto and can be implemented with various modifications within the scope of the claims, the detailed description of the invention, and the accompanying drawings, and this is also the present invention. It is natural that it falls within the scope of .

10...Transfer unit 11...Ingot
20...feeding unit 21...feed roller
30...mobile bogie 31...first bogie body
31a...First driving wheel 33...Second bogie body
32a...second drive wheel 35...inner roller
40...rotation bracket 41...hinge
50... driving part 51... wire member
53...Drive motor 60...Ingot pot
61..Molten zinc

Claims (7)

A device that automatically puts an ingot into an ingot pot where the ingot is melted,
A transfer unit that transfers the ingot;
A rail member installed between the transfer unit and the ingot pot;
A mobile cart installed to be movable along the rail member and moving the ingot transferred from the transfer unit to the ingot pot position;
a feeding unit installed between the transfer unit and the ingot pot to supply the ingot to the mobile cart;
a rotation bracket in which the ingot is located and rotatably installed on the mobile cart to insert the ingot into the ingot pot when rotated; and
a driving unit that provides rotational driving force to the rotating bracket;
Including,
The mobile bogie is,
A first bogie body with a first drive wheel installed at the lower part to be movable along the rail member;
A supply space through which the ingot is supplied is formed between the first bogie body, and a second drive wheel is installed at the lower portion to be movable along the rail member together with the first bogie body. ; and
an internal roller rotatably installed between the first bogie body and the second bogie body to move the ingot;
Including,
An ingot insertion device for a hot-dip galvanizing bath, wherein the rotation bracket is rotatably installed between the first bogie body and the second bogie body. According to paragraph 1,
The transfer unit is,
An ingot feeding device for a hot-dip galvanizing bath, which is a conveyor that transports the ingots to the feeding unit location with a plurality of the ingots seated on the top. According to paragraph 2,
The feeding unit is,
An ingot feeding device for a hot-dip galvanizing bath, including a supply roller rotatably installed between the transfer unit and the ingot pot to supply the ingot to the mobile cart. delete According to paragraph 1,
The rotation bracket is,
a bracket body whose side is rotatably installed on one side of the first and second bogie bodies in the direction of the ingot pot, inside which the ingot moved by the feeding unit is positioned; and
a bracket roller rotatably installed inside the bracket body to rotationally support the ingot within the bracket body;
Ingot insertion device of a hot-dip galvanizing bath, including a. According to clause 5,
The rotation bracket is,
One side protrudes to the outside of the moving cart, and when rotating, one side is inclined toward the inside of the ingot pot, and the ingot is moved toward one side of the rotation bracket by its own weight. An ingot insertion device for a hot-dip galvanizing bath. According to clause 6,
The driving unit,
a wire member on one side of which is connected to the rotation bracket and supports the rotation state of the rotation bracket; and
a drive motor connected to the other side of the wire member and controlling the rotation angle of the rotation bracket by winding the wire member;
Ingot insertion device of a hot-dip galvanizing bath, including a.

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