KR100907401B1 - Apparatus for providing an ingot in the continuous galavnizing process - Google Patents

Abstract

The present invention relates to an apparatus for injecting an ingot of a cubic structure into a plating bath of a hot dip galvanizing process, comprising: a conveying unit having a conveying means for conveying the ingot to a plating bath; Holding means for gripping an ingot in a horizontal state, horizontal moving means for reciprocating the holding means in a horizontal direction between the transfer part and the plating bath, and vertical moving means for reciprocating the holding means in a vertical direction In order to manage the level of the molten zinc hot water in the plating bath, when the ingot is put into the plating bath, it is possible to prevent damage of the refractory that is built up in the plating bath and also prevent the fluctuation of the molten zinc hot water. It can improve product quality and prevent premature damage of plating equipment.

Clamp clamp, Seating roller, Connecting shaft, Electric motor

Description

Ingot input device for hot dip galvanizing process {Apparatus for providing an ingot in the continuous galavnizing process}             

1 is a schematic view of a typical hot dip galvanizing facility;

2 is a view showing an ingot input device according to a conventional embodiment;

3 is a view showing an installation state of the ingot input device of the hot dip galvanizing process according to the present invention;

Figure 4 is a perspective view of the ingot input device of the hot dip galvanizing process according to the present invention;

5 is a view showing a vertical transfer means of the ingot input device of the hot dip galvanizing process according to the present invention;

Figure 6 is an enlarged view showing a coupling state of the electric motor and the gear shaft of the vertical transfer means of the ingot injection device of the hot dip galvanizing process according to the present invention;

Figure 7 is a view showing the forward and backward means of the ingot input device of the hot dip galvanizing process according to the present invention;

8 is a view showing a horizontal transfer means of the ingot input device of the hot dip galvanizing process according to the present invention;

Figure 9 is an enlarged view showing a coupling state of the electric motor and the screw of the horizontal transfer means of the ingot injection device of the hot dip galvanizing process according to the present invention.

<Description of Symbols for Major Parts of Drawings>

2: plating bath

20: clamping clamp

35, 43, 56: electric motor

24: fixed cylinder

25 extension member

27: connecting shaft

34, 41, 53: gearbox

36, 44, 57: rangefinder

45: fixed body

50: main body

51: body support stand

60: fixed base plate

The present invention relates to a device for injecting a solid ingot into the plating bath in the hot dip galvanizing process, and more particularly, a solid ingot to be injected into the plating bath during the galvanizing operation for a constant level management The present invention relates to a device for smoothly inserting ingots by eliminating frequent causes of equipment burnout during clamping and the negative effects on the surface of the product due to molten zinc level flow.

In general, the hot dip galvanizing process is a process of plating a zinc by passing a strip through a plating bath. As shown in FIG. 1, the hot dip galvanizing process is performed in the heating furnace 1 and extracted in a heated state at an appropriate temperature. Zinc is plated on the surface of the steel sheet 7 which has passed through). In the plating amount controller 3, the amount of zinc plating plated on the surface of the steel sheet 7 is controlled, and the steel sheet 7 proceeds to a later step in a cooled state via the cooling stand 4 and the driving roll 5. .

The zinc level of the plating bath 2 is lowered because a certain amount of liquid zinc is buried out on the surface of the steel sheet 7 that is performed during the hot dip galvanizing as described above. As described above, when the zinc level is lowered, as shown in FIG. 2, the ingot 11 of the solid is transferred to the plating bath 2 along the conveyor 8 using the clamp 9 to melt the zinc. Reward your level. Reference numeral 10 is an electric motor for moving the clamp (9).

At this time, since only one side portion of the ingot 11 is fastened to the clamp 9, when the ingot 11 is transported along the conveyor 8 in an inclined state without being horizontal, the plating bath ( 2) to interfere with the guide 12 for induction leading to the overload is induced as a result of the overload in the electric motor 10, the burnout of the equipment is generated.

On the other hand, as the clamp 9 moves along the rail 13, the ingot 11 is melted while gradually being introduced into the plating bath 2 along the guide guide 12. The lower part of the ingot 11 is melted by the heat of the plating bath 2 while the clamp 9 reaches the end of the rail 13, and the upper part which is fastened to the clamp 9 is unmelted. Is maintained. The upper portion of the ingot 11 is dropped into the plating bath by the release action of the clamp (9). This solid ingot damages the refractory brick (not shown) built up inside the plating bath.

On the other hand, in the case where the high-pressure air injected from the plating amount controller 3 for controlling the plating amount is synchronized with the flowing zinc flowing, the zinc in the form of agglomerate is attached to the surface of the steel sheet advancing or attached to the facilities around the plating bath. Cause.

When the above problems are caused, the continuous line of the hot dip galvanizing process is operated at a low speed or causes line stoppage and in particular degrades the quality of the plated steel sheet.

The present invention has been made in order to solve the conventional problems as described above, prevents the flow of the molten zinc layer when the solid ingot to the plating bath of the hot dip galvanizing process and also built in the bottom layer of the plating bath It is an object of the present invention to provide an ingot input device of a hot dip galvanizing process that can prevent the breakage of a firebrick to improve the quality of a plated steel sheet.

In order to achieve the above object, according to the present invention, an apparatus for injecting the ingot of the cube structure into the plating bath of the hot dip galvanizing process, the transfer unit having a transfer means for transferring the ingot to the plating bath side, and the transfer A gripping means positioned above the means for gripping the ingot in a horizontal state, a horizontal moving means for reciprocating the gripping means in a horizontal direction between the transfer part and the plating bath, and reciprocating the gripping means in the vertical direction Characterized in that it consists of vertical movement means for moving.

Best Mode for Carrying Out the Invention Preferred embodiments of the present invention will now be described with reference to the accompanying drawings, in which like components employ like reference numerals.

First, the ingot 11 introduced into the plating bath 2 in order to compensate for the lowering of the water level of the plating melt layer in the plating bath 2 for the hot dip galvanizing process has a cube structure. The transfer part has a conveyor for transferring the ingot from the ingot supply part (not shown) to the plating bath 2 side. One end of the conveyor is provided with a seating roller 14a on which the ingot 11 is seated.

The upper portion of the seating roller 14a is provided with a connecting shaft 27 installed in the horizontal direction, and the connecting shaft 27 is manufactured in a rod shape having a screw 30 formed at a rear portion thereof. The rear of the connecting shaft 27 is provided with a gear box 31 is mounted with a gear shaft 33 extending in the vertical direction on one side. The rear end of the connecting shaft 27 extending through the gear box 31 is provided with a first electric motor 35 having a gear assembly 34 engaged with the screw 30 of the connecting shaft 27. By the operation of the first electric motor 35, the connecting shaft 27 is rotated in a predetermined direction. Reference numeral 36 is a distance meter for calculating the moving distance of the connecting shaft.

And, in front of the connecting shaft 27, a gripping means for gripping the ingot 11 seated on the seating roller 14a of the transfer part in a horizontal state is provided. The holding means has a connecting rod (21) for connecting the lower portion of the extension member (25) extending vertically downward from the square connecting shaft (26) spaced at predetermined intervals on the connecting shaft (27). Both ends of the connecting rod 21 are provided with a clamping clamp 20 intersecting with each other about the connecting rod 21, and the upper end of the clamping clamp 20 is coupled at the coupling rod 22 through the connecting member. The rod end of the fixed cylinder 24 fixed to the connecting shaft 27 is connected to the coupling rod 22 through a circular guide 23. As the coupling rod 22 moves up and down by the expansion and contraction of the fixed cylinder 24, the clamp clamp 20 pivots about the connecting rod 21, thereby explaining the ingot 11 as described below. The fastening operation or the fastening release operation for the.

On the other hand, the gear shaft 33 is movably coupled to the guide type guide 40 which is directly welded on the fixed body 45 in the vertical direction. The upper part of the induction guide 40 is provided with a gear box 41 in which a rotary gear 41a is fitted, which meshes with the gear shaft 33. The rotary gear 41a is connected to the second electric motor 43 through the circular shaft 46. As the rotary gear 41a rotates by the operation of the second electric motor 43, the gear shaft 33 moves in the up and down direction, and in conjunction with this, the connecting shaft 27 moves in the up and down direction. Reference numeral 44 is a distance measuring device for measuring the Shanghai dong distance of the gear shaft 33, reference numeral 60 is a fixed support plate on which the second electric motor 43 is supported.

The fixed body 45 is slidably mounted to a pair of main body support 51 which is installed in the horizontal direction while being supported by the main body 50. A gear shaft 52 is provided on each main body support 51, and the fixed body 45 is connected to each other by the fixed support plate 60. A third electric motor 56 is provided on the fixed support plate 60, and the rotation shaft of the third electric motor 56 is connected to the connecting shaft 54 having the rotary gears 53a at both ends thereof to enable power transmission. do. The rotary gear 53a is embedded in the gear box 53 in a state of being engaged with the gear shaft 52. Therefore, as the rotary gear 53a rotates by the operation of the third electric motor 56, the fixed body 45 moves along the main body support 51. As shown in FIG. Reference numeral 57 is a distance measuring device for measuring the moving distance of the fixed body 45, 55 is a gear box to protect the coupling portion of the rotation shaft and the connecting shaft 54 of the third electric motor (56).

Hereinafter, the operation of the ingot input device according to the present invention will be described.

First, before inserting the ingot 11 into the plating bath 2, the connecting shaft 27 is recovered in a state located above the induction guide 40, spaced apart from the plating bath 2, and the main body 45. Is located at one end of the body support (51).

The ingot 11 is transferred from the ingot supply part (not shown) to the seating roller 14a along the conveyor from the ingot supply part (not shown) to inject the ingot 11 into the plating bath 2 during the hot dip galvanizing process.

Then, the fixed body 45 is moved from one end of the main body support 51 to the other end by the operation of the electric motor 55 so that the connecting shaft 27 is located above the seating roller 14a. When the connecting shaft 27 is located on the seating roller 14a, the operation of the third electric motor 56 is stopped, after which the second electric motor 43 starts to move the connecting shaft 27 downward. . After the connecting shaft 27 is lowered by a predetermined distance, the rod end of the fixed cylinder 24 is contracted and the coupling rod 22 is moved upward, and the clamp clamp 20 grips both ends of the ingot 11.

After that, when the first electric motor 35 is operated to extend the connecting shaft 27 to the plating bath side, the ingot 11 is moved to the plating bath 2 in a horizontal state by the clamp clamp 20. When the ingot 11 is located on the molten plating layer of the plating bath 2, the second electric motor 43 is moved again to move the connecting shaft 27 downward so as to be held by the clamp clamp 20. The net 11 is immersed in the plating bath (2).

At this time, since the moving distance of the object to be moved is set in the distance measuring devices 36, 44, and 57, the electric motors 35, 43, and 56 move by the set value set in the distance measuring device to accurately position the object. To be set.

On the other hand, while the ingot 11 is gripped by the clamp clamp 20, the third electric motor 56 is operated to move the fixed body 45 to another position, and then the electric motors 35 and 43 are operated. By doing so, the insertion position of the ingot 11 in the plating bath 2 can be adjusted.

As described above, in the state in which the ingot 11 is immersed in the plating bath 2 to a predetermined depth, the fixed cylinder 24 is operated in the reverse direction, thereby tightening the clamping state of the clamp clamp 20 to the ingot 11. When released, the ingot 11 falls into the plating bath 2. At this time, since the lower surface of the ingot 11 is kept in a horizontal state with respect to the molten zinc bath surface of the plating bath (2), the resistance applied from the molten zinc is relatively increased to decrease the falling speed of the ingot 11 As a result, the ingot 11 is gradually immersed in the plating bath.

Then, after dropping the ingot 11 into the plating bath 2, the connecting shaft 27 is returned to the standby position. In addition, when the level of molten zinc in the plating bath 2 is restored to normal, and the closing operation of the ingot 11 into the plating bath 2 is completed, the fixed body 45 is also returned to the standby position.

According to the present invention, when the ingot is put into the plating bath in order to manage the level of the molten zinc hot water in the plating bath, it is possible to prevent damage of the refractory built up in the plating bath and to prevent the fluctuation of the molten zinc hot water surface. It can improve the quality and prevent premature damage of the plating equipment.

The foregoing is merely illustrative of the preferred embodiments of the present invention and those skilled in the art to which the present invention pertains recognize that modifications and variations can be made to the present invention without departing from the spirit and gist of the invention as set forth in the appended claims. shall.

Claims (3)

In the device for injecting the ingot of the cube structure into the plating bath of the hot dip galvanizing process, A holding means including a plurality of pairs of clamp clamps for fastening both ends of the ingot to hold the ingot horizontally; A transfer part having a transfer means for reciprocating the holding means located at the upper side to transfer the ingot to the plating bath side; Horizontal movement means for reciprocating the holding means in a horizontal direction between the transfer part and the plating bath; It includes a vertical movement means for reciprocating the holding means in the vertical direction, The horizontal moving means calculates a connecting shaft provided with the gripping means, a screw formed behind the connecting shaft, a first electric motor for moving the connecting shaft in a horizontal direction through the screw, and a moving distance to move the connecting shaft. The vertical movement means calculates a gear shaft, a second electric motor for moving the gear shaft in an up and down direction, and a movement distance to move the gear shaft, and the transfer means includes a fixed body and the fixed body in a forward and backward direction. A third electric motor to be transferred to and a moving distance of the fixed body to be moved, wherein the first, second and third electric motors are calculated from each of the horizontal moving means, the vertical moving means, and the transfer means. Ingot input device of the hot-dip galvanizing process, characterized in that it operates as long as the movement distance. The method of claim 1, The gripping means comprises a clamp clamp for fastening both ends of the ingot, and a movable means for fastening or releasing the clamp clamp, one end of the movable means being fixed to the horizontal moving means. Ingot input device for hot dip galvanizing process. The method of claim 2, One end of the horizontal moving means is ingot input device of the hot dip galvanizing process characterized in that the vertical movement means is supported to be movable in the vertical direction.

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