KR101480888B1 - Variable metal pump - Google Patents

Abstract

The present invention is a variable metal pump provided on both sides of a snout provided so as to allow a tip to be submerged in molten zinc filled in a plating tank and discharging a zinc material on the plating surface to the outside through a Snart interior space, The metal pump includes a metal pump body having a discharge space communicating with the inner space of the snout; A rotation shaft installed inside the metal pump body; Rotating means for rotating the rotating shaft; An impeller installed at an end of the rotary shaft and rotating simultaneously with the rotary shaft, the impeller being formed so that an outer side thereof is close to an inner surface of the metal pump body and removes a subassembly and a dross fixed to the inner surface of the metal pump body during rotation; Wherein the metal pump main body includes elevating means for elevating only the rotating shaft without lifting the metal pump body, the rotating means being provided outside the metal pump body, the rotating means and the rotating shaft being connected by a universal joint, And the elevating means is connected to the rotating means to elevate and lower the rotating means to thereby raise and lower the rotating shaft connected to the elevating means.
According to the present invention, by forming the rotary shaft of the metal pump so as to be able to move up and down by the elevating means, it is possible to remove the subassembly and the dross which are fixed to the metal pump without lifting the entire slug.

Description

Variable metal pump {VARIABLE METAL PUMP}

The present invention relates to a variable metal pump, and more particularly, to a variable metal pump capable of removing a submerged material and a dross adhered to a metal pump without lifting the entire slump To a variable metal pump.

Plated steel sheets, especially hot-dip galvanized steel sheets, are being used for general building materials and automobile exterior panels that require strict quality control due to their excellent corrosion resistance.

As shown in FIG. 1, the steel sheet 20 of the cold-rolled coil is continuously passed through a paper prill (not shown) and a welder (not shown) The heated steel sheet 20 is heat-treated in the heating furnace 10 so as to remove the residual stress, and after passing through the Snart 12 in a state where the heated steel sheet 20 is maintained at a temperature suitable for galvanizing, 40).

In this case, a sink roll 30 for changing the proceeding direction of the steel plate 20 is installed in the plating tank 40, and the heating furnace 10, the Snart 12, the plating tank 40, 30 and the stabilizing roll 60 are sequentially adjusted so that the amount of plating is adjusted by the air knife 50 disposed on the upper portion of the plating tank 40.

Thereafter, the steel plate 20 whose plating amount has been adjusted is cut through a cutter (not shown) through a roughing mill (not shown), subjected to appropriate surface roughness and shape correction, and then wound on a tension reel It is produced by plating coil product.

As shown in FIG. 2, zinc oxide (A) is generated on the inner surface of the Snooth 12 by the evaporation of zinc vapor as an ash and condensed. When the evaporated zinc particles are condensed The zinc alloy A adheres to the inner surface of the Snart 12 and accumulates and accumulates on the surface of the steel sheet 20 floating and floating on the interface of the molten zinc in the plating bath 40 when the size exceeds the critical level Thereby causing surface defects of the steel plate 20. [

A metal pump is formed on both sides of the snout 12 to remove the submerged material A, and the submerged material A in the snout 12 is discharged to the outside by the operation of the metal pump.

In such a case, the metal pump is often stopped due to frequent adhesion of the zinc material or the dross to the metal pump.

In order to prevent such malfunctions, it is necessary to raise and lower the snout 12 to the upper part of the interface of the molten zinc to discharge the subassemblies or dross fixed to the metal pump to the outside. In this case, There is a problem that the vibration occurs and the submerged material falls.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a metal pump which is capable of being lifted and lowered by a lifting means, The present invention is to provide a variable metal pump capable of removing the metal pump.

According to the present invention, there is provided a method of manufacturing a plating tank, comprising the steps of: providing at both sides of a slant installed on a molten zinc filled in a plating tank so that a tip thereof is submerged, As a pump,
The variable metal pump includes a metal pump body having a discharge space communicating with the inner space of the snout; A rotation shaft installed inside the metal pump body; Rotating means for rotating the rotating shaft; An impeller installed at an end of the rotary shaft and rotating simultaneously with the rotary shaft, the impeller being formed so that an outer side thereof is close to an inner surface of the metal pump body and removes a subassembly and a dross fixed to the inner surface of the metal pump body during rotation; Wherein the metal pump main body includes elevating means for elevating only the rotating shaft without lifting the metal pump body, the rotating means being provided outside the metal pump body, the rotating means and the rotating shaft being connected by a universal joint, The elevating means is connected to the rotating means to elevate the rotating means, thereby further elevating the rotating shaft connected to the elevating means.

The spiral screw may be formed in an axial direction along an outer circumference of the rotary shaft and spaced apart from an upper portion of the impeller. The outer end of the spiral screw may be installed close to the inner surface of the metal pump body, And to remove the subassembly and the dross adhered to the inner surface of the metal pump main body.

The auxiliary impeller further includes an auxiliary impeller installed on the rotary shaft and rotated at the same time as the rotary shaft to be spaced apart from the upper portion of the impeller, wherein an outer end of the auxiliary impeller is installed close to the inner surface of the metal pump body, And to remove the subassembly and the dross adhered to the inner surface of the main body.

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Thus, by forming the rotary shaft of the metal pump so as to be able to move up and down by the elevating means, it is possible to remove the subassembly fixed to the metal pump and the dross without lifting the entire Snart.

Figures 1 and 2 are views of the prior art.
3 is a perspective view of a variable metal pump according to the present invention.
4 to 6 are side cross-sectional views of a variable metal pump according to the present invention,

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

3 and 4, the variable metal pump according to the present invention is provided on both sides of the snout 12 and forms a discharge space therein, in which the inside of the snout 12 and the discharge space communicate with each other A rotating shaft 200 installed inside the metal pump body 100; a rotating means 300 for rotating the rotating shaft 200; and a rotating shaft 300 installed at the end of the rotating shaft 200 An impeller 210 rotated at the same time as the rotary shaft 200 and a lifting means 400 for lifting and rotating the rotary shaft 200.

First, the metal pump main body 100 is a substantially rectangular box-shaped member having a space formed therein, and is installed at both lower portions of the snout 12. A plurality of communication holes 130 formed to penetrate the metal pump main body 100 and the snout 12 at the same time are formed so that the inner space of the metal pump main body 100 and the inside of the snout 12 are communicated with each other . The metal pump body 100 is provided at its lower portion with a discharge portion 110 formed to open at an upper portion thereof and is installed to be in communication with the internal space of the metal pump body 100. The open upper portion of the discharge portion 110 is formed to have an area larger than the width of the metal pump body 100 so that the opened portion is exposed to the outside of the metal pump body 100. That is, the inner space of the metal pump body 100 communicates with the discharge hole 120 provided to communicate with the discharge portion 110 and to be exposed to the outside of the metal pump body 100.

On the other hand, the rotary shaft 200 is a circular rod having a predetermined diameter and is installed to be pulled down from the upper part of the metal pump body 100. The end of the upper end of the rotating shaft 200, which is located outside the metal pump body 100, is connected to the rotating means 300 by a plurality of universal joints 310. By driving the rotating means 300, The rotary shaft 200 is rotated. The rotating means 300 may be a general electric motor or the like and the driving shaft of the electric motor is connected to the rotating shaft 200 by the universal joint 310. As described above, when the rotating means 300 is located outside the metal pump body 100, the metal pump body 100 moves away from the metal pump body 100 having a relatively high temperature working environment, do.

Further, the impeller 210 is a propeller formed of a plurality of blades, and is installed at the lower end of the rotating shaft 200 and rotated together with the rotating shaft 200. At this time, the outer side of the impeller 210 is formed so as to be close to the inner surface of the metal pump body 100, so that the subassembly and the dross adhered to the inner surface of the metal pump body 100 when the impeller 210 rotates can be easily removed have.

The elevating means 400 is connected to the rotating means 300 to elevate the rotating means 200 and the impeller 210 by moving the rotating means 300 up and down. The elevating means 400 is connected to the rotating means 300 to lift and lower the rotating shaft 200 and the impeller 210. However, the present invention is not limited to this, and the elevating means 400 may be installed directly on the rotating shaft 200, And the impeller 210 only.

In the variable metal pump according to the present invention configured as described above, the impeller 210 is rotated by the rotating means 300 to suck the zinc particles and dross in the Snart 12 through the communication hole 130, So that the submerged material and dross sucked into the pump main body 100 are discharged to the outside through the discharge hole 120. As the work process continues for a long time, when the ash material and the dross are fixed to the inner surface of the metal pump body 100 and the impeller 210, the elevating means 400 is operated to move the impeller 210 up and down, The inner surface of the pump main body 100 and the ashes and dross adhered to the impeller 210 are removed.

Meanwhile, the variable metal pump according to the present invention may further include a screw 220, as shown in FIG.

The screw 220 is a helical member formed in the axial direction along the outer periphery of the rotary shaft 200 and is formed to be spaced apart from the impeller 210 on the upper portion of the impeller 210. At this time, the outer end of the screw 220 is installed close to the inner surface of the metal pump body 100. By using the screw 220 having the above-described structure, it is possible to more effectively remove the subassembly and the dross which are fixed to the inner surface of the metal pump body 100.

6, the variable metal pump according to the present invention is installed on the rotary shaft 200 and rotated simultaneously with the rotary shaft 200. The impeller 210 is spaced apart from the impeller 210 by an upper portion of the impeller 210 And an auxiliary impeller 230 installed thereon.

The auxiliary impeller 230 is a propeller formed of a plurality of blades, and is installed at a middle portion of the rotating shaft 200 and rotated together with the rotating shaft 200. At this time, the outer side of the auxiliary impeller 230 is formed to be close to the inner surface of the metal pump body 100, so that the subassembly and dross fixed to the inner surface of the metal pump body 100 when the auxiliary impeller 230 rotates can be easily Can be removed.

In the variable metal pump according to the present invention, the rotation shaft 200 of the metal pump can be raised and lowered by the elevating means 400, so that the metal pump body (not shown) 100 and the dross can be removed.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. It will be understood that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims.

10: Heating furnace 12: Snout
20: Steel plate 30: Think roll
40: Plating tank 50: Air knife
60: Stabilizing roll 100: Metal pump body
110: exhaust part 120: exhaust hole
130: communication hole 200:
210: impeller 220: screw
230: auxiliary impeller 300: rotating means
310: universal joint 400: lifting means

Claims (5)

A variable metal pump provided on both sides of a snout installed so that its tip is immersed in molten zinc filled in a plating tank and discharging a zinc material on the plating surface to the outside through a Snart interior space,
The variable-
A metal pump body having a discharge space communicating with the inner space of the snout;
A rotation shaft installed inside the metal pump body;
Rotating means for rotating the rotating shaft;
An impeller installed at an end of the rotary shaft and rotating simultaneously with the rotary shaft, the impeller being formed so that an outer side thereof is close to an inner surface of the metal pump body and removes a subassembly and a dross fixed to the inner surface of the metal pump body during rotation;
Wherein the metal pump main body includes a lifting means for lifting only the rotary shaft without lifting the metal pump body,
Wherein the rotating means is provided outside the metal pump body, and the rotating means and the rotating shaft are connected by a universal joint,
Wherein the elevating means is connected to the rotating means to elevate and lower the rotating means to thereby raise and lower the rotating shaft connected to the elevating means. The method according to claim 1,
And a spiral screw formed axially along the outer periphery of the rotary shaft and spaced apart from the upper portion of the impeller,
And an outer end of the helical screw is installed close to the inner surface of the metal pump body so as to remove the subassembly and the dross adhered to the inner surface of the metal pump body. The method according to claim 1,
Further comprising an auxiliary impeller installed on the rotary shaft and rotated simultaneously with the rotary shaft, the auxiliary impeller being spaced apart from the upper portion of the impeller,
And an outer end of the auxiliary impeller is disposed in proximity to an inner surface of the metal pump main body so as to remove the submerged member and the dross adhered to the inner surface of the metal pump main body. delete delete

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