KR101403921B1 - Actuator for removing ash of snout - Google Patents

Abstract

A Snooth foreign body discharge actuator capable of effectively discharging foreign matter from Snooth is introduced.
To this end, according to the present invention, there is provided an actuator for discharging foreign substances on a bath surface of a Snart, comprising: an inlet port through which a plating liquid containing a foreign substance flows, A pump housing in which a discharge port for discharging a plating liquid containing a foreign substance is formed on the other side; A rotating shaft having a propeller for discharging the plating liquid at its tip and being rotatably installed in the pump housing; A driving motor fixedly installed on the upper portion of the pump housing to be driven to be connected to the rotating shaft; And a side flow prevention plate disposed on the upper side of the propeller in order to prevent a side stream from rising during rotation of the propeller, wherein a cooling housing surrounding the rotation shaft is provided between the pump housing and the drive motor, A cooling pipe through which cooling gas flows is inserted into one side of the cooling housing, and a bearing housing for supporting the rotation shaft is provided inside the cooling housing through a connecting bearing. Heat shielding and tight sealing are provided between the cooling housing and the pump housing The heat insulating unit is provided.

Description

TECHNICAL FIELD [0001] The present invention relates to an actuator for discharging foreign matter,

The present invention relates to an actuator for discharging a foreign matter of Snooth. More particularly, the present invention relates to an actuator for discharging foreign matter of Snooth, which prevents a rising action of a plating liquid due to occurrence of a side stream when a foreign object is discharged.

Generally, a hot-dip galvanized steel sheet is heat-treated at a predetermined temperature in an annealing furnace, and then continuously supplied into the hot-dip galvanizing bath through the inside of the Snart, and is galvanized. The amount of galvanized steel is controlled by an air knife, The steel sheet is subjected to alloying heat treatment and then continuously cooled in the air cooling zone and advanced to the top roll.

At this time, the zinc evaporation (Ash: ash) generated in the Snout is evaporated to the upper part of the Snout, and then falls down toward the Snout bottom bath surface by its own weight. Thereby causing surface defects.

As a method for removing the ash in the snout, conventionally, "a device for removing foreign matter on the surface of a bath surface inside Snooth" (Patent Registration No. 10-0831061) is known.

As shown in FIG. 1, a conventional hot water surface foreign matter removal device in Snooth has a lower panel 210 installed at the lower end of the Snart 200, and a lower panel 210 having a width and a length, A vertical panel 220 protruded upward from the edge of the steel plate advancing hole 211 and formed between the snout 200 and the vertical panel 220 A housing 230 installed on the outer side wall of the housing 200 and a driving motor 240 installed inside the housing 230. The housing 230 is provided with a discharge hole 201, And a rotary vane 250 installed so as to be immersed in a hot-dip galvanizing bath in a state of being connected to the rotary shaft 241 of the driving motor 240.

That is, when the driving motor 240 is operated, the rotating blades 250 provided on the rotating shaft 241 of the driving motor 240 are rotated, and the plating liquid containing the foreign substances is discharged from the discharge pipe 232, respectively.

In this prior art, however, a clearance for rotation of the rotary vane is formed between the rotary vane and the peripheral side wall of the rotary vane. When the rotary vane rotates, a sidestream is generated in the peripheral side wall of the rotary vane, The pumping efficiency deteriorates. Particularly, when the rotating blades are worn, the pumping efficiency is greatly deteriorated. As a result, the contamination due to the foreign substances in the housing due to the synergistic action of the plating liquid Problems such as deepening were caused.

Also, high temperature is transmitted through the pump housing and the rotating shaft, which are in contact with the high-temperature plating solution of about 450 degrees, to cause deterioration and damage of the bearing portion.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems and to provide a Snooth-out foreign matter discharging actuator for improving the pumping efficiency and effectively discharging the plating liquid.

In order to achieve the above object, according to the present invention, there is provided an actuator for discharging a foreign matter on a bath surface in a snout, comprising a pump housing, a rotary shaft, a driving motor, Prevention plate and an insulating unit. At this time, the pump housing is formed at one side so that an inlet through which the plating liquid containing the foreign substance flows is connected to the inside of the Snout, an outlet for discharging the plating liquid containing the foreign body is formed at the other side, A propeller is provided at a tip end of the pump housing and is rotatably installed in the pump housing. The drive motor is fixed to the upper portion of the pump housing so as to be driven by the rotation shaft. A cooling pipe for enclosing the rotating shaft is provided between the pump housing and the driving motor, a cooling pipe through which cooling gas flows is inserted into one side of the cooling housing, A bearing which supports the rotating shaft through a connecting bearing, The housing is installed, between the cooling housing and the pump housing the heat insulating unit is provided for the heat transfer block and close sealing.

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Preferably, the heat insulating unit includes a sealing cover for enclosing the rotating shaft via a first sealing material, a base plate provided on an outer circumferential surface of the sealing cover, and an insulating plate and a second sealing material provided between the base plate and the pump housing .

Preferably, the counterflow prevention plate includes: a support portion for supporting the rotation shaft; a latching protrusion protruding from the upper end of the support portion in the outer diameter direction to be fixed to the pump housing; a protrusion protruding in the center direction from a lower end of the support portion, And a blocking jaw that blocks rising of the side stream.

Preferably, the rotating shaft includes a connecting shaft which is driven and connected to the driving motor via a connecting shaft coupling, a rotating shaft provided with a propeller at a lower end thereof, and a heat insulating flange connecting between the connecting shaft and the rotating shaft.

According to the present invention, the following remarkable effects can be realized.

First, the present invention has an advantage that the pumping efficiency of the propeller is improved and the plating liquid containing the foreign substance can be effectively discharged.

Second, the present invention is advantageous in that the plating solution in the housing is acted up so that contaminants in the plating solution can be prevented from being contaminated inside the housing.

Third, the present invention is advantageous in that the high temperature transmitted from the pump housing and the direct transfer heat transmitted from the rotary shaft constituted by the propeller are prevented from being transmitted to the bearings and the motor, thereby preventing damage to the motor and the bearing, thereby extending service life.

1 is a perspective view showing a conventional foreign matter discharge actuator of Snooth.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]
3 is a configuration diagram showing a foreign matter discharge actuator of Snooth according to the present invention.
FIGS. 4A and 4B are enlarged views of a heat insulating flange and a heat insulating unit of a foreign substance discharging actuator according to the present invention. FIG.
FIGS. 5A and 5B are diagrams showing an operating state according to a state in which a counterflow prevention plate is installed in a foreign matter discharging actuator of Snooth according to the present invention. FIG.

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

FIG. 2 is a view showing a foreign matter discharge actuator of Snooth according to the present invention, FIG. 3 is a view showing a foreign matter discharge actuator of Snooth according to the present invention, and FIGS. 4a to 4b are cross- Fig. 3 is an enlarged view of a heat insulating flange and a heat insulating unit of a foreign matter discharge actuator of Fig.

2 to 4B, the foreign substance discharge actuator of the present invention includes a pump housing 100, a rotating shaft 200, a driving motor 300, and a flow-preventing plate 400 .

Specifically, the pump housing 100 is installed so as to be immersed in a hot dip galvanizing bath, a receiving space for temporarily storing the plating solution supplied with the foreign substance is formed, and a plating solution containing a foreign substance is provided on one side of the pump housing 100 And an outlet 120 through which the introduced plating liquid is discharged is formed on the other side.

A drive motor 300 is mounted on the upper portion of the pump housing 100 through a cooling housing 500. The cooling housing 500 is positioned between the pump housing 100 and the driving motor 300 to block the high temperature transferred to the driving motor 300. To this end, cooling gas is supplied to one side of the cooling housing 500 The incoming cooling piping 510 is inserted. In this embodiment, nitrogen gas for cooling is used to prevent the driving motor 300 from being heated.

A plurality of exhaust holes 521 are formed in the lower side of the lower cooling housing 500b to discharge the cooling gas introduced through the cooling pipe 510 to the outside of the cooling housing 500. In particular, When the cooling gas introduced into the housing 500b flows into the pump housing 100 through the first sealing member 545, a discharge pipe 520 for discharging the cooling gas is provided.

The cooling housing 500 includes an upper cooling housing 500a and a lower cooling housing 500b. The rotary shaft 200 is driven and connected to the inside of the upper cooling housing 500a through the driving shaft of the driving motor 300 and the coupling shaft coupling and the coupling bearing 531 is used inside the lower cooling housing 500b A bearing housing 530 supporting the rotating shaft 200 is provided.

The rotating shaft 200 is driven and connected to the driving shaft of the driving motor 300 through a coupling shaft coupling and a propeller 210 is provided at the lower end of the rotating shaft 200 to connect the outlet 120 of the pump housing 100, . The rotating shaft 200 includes a connecting shaft 200a drivingly connected to the driving motor 300 via a connecting shaft coupling, a rotating shaft 200c provided with a propeller 210 at a lower end thereof, And a heat shield end flange 200b connecting between the connection shaft 200a and the rotary shaft 200c.

Particularly, at a connection portion between the cooling housing 500 and the pump housing 100, a heat insulating unit 540 for tightly sealing them is provided. The heat insulating unit 540 is configured to block thermal energy transmitted from the pump housing 100 to the cooling housing 500. The thermal energy of the pump housing 100 causes the connection bearings 531 and the drive motor 300 to overheat ≪ / RTI >

This heat insulating unit 540 is composed of a sealing cover 541, a base plate 542, a heat insulating plate 543, a first sealing member 545 and a second sealing member 544. Here, the sealing cover 541 is formed in a cylindrical shape surrounding the rotating shaft 200 through the first sealing member 545, and a lip chamber is provided in the space between the rotating shaft 200. The base plate 542 is installed on the outer circumferential surface of the sealing cover 541 and can be supported on the inner wall of the pump housing 100. A heat insulating plate 543 is provided below the base plate 542, And a second sealing material 544 is provided on the outer surface. And a side flow prevention plate 400 is disposed under the heat insulating plate 543. [

The side flow prevention plate 400 is disposed on the upper side of the propeller 210 in the pump housing 100 to prevent the side flow generated when the propeller 210 rotates. The side flow prevention plate 400 includes a support portion 410 for supporting the stopping jaw portion 420 and the blocking jaw 430 and a support portion 410 projecting in the outer diameter direction from the upper end of the support portion 410 and fixed to the pump housing 100 And a blocking jaw 430 protruding inwardly from a lower end of the support portion 410 so as to have a diameter smaller than the diameter of the discharge port 120 to block the rise of the side stream during rotation of the propeller 210 do.

FIGS. 5A and 5B are diagrams illustrating an operation state of the Snart's foreign matter discharge actuator according to the state in which the anti-skid plate is installed according to the present invention.

5A, even if a side stream is generated at the side wall of the discharge port 120 around the propeller 210, the blocking jaws 430 of the side flow prevention plate 400 Is guided toward the propeller 210, it is possible to prevent the plating liquid from flowing back upward along the side wall of the discharge port 120.

5B, when the sideways prevention plate 400 is not provided, when the sidewall is generated at the sidewall of the discharge port 120 around the propeller 210, the plating liquid flows along the sidewall of the discharge port 120 As the air flows backward in the upward direction, the propeller 210 is worn out excessively, the pumping efficiency is lowered, and the chamber in the housing is contaminated.

Hereinafter, the discharge efficiency by the side stream eddy current is compared between the present invention and the conventional art as follows.

Table 1 below shows the influence of the exhaust efficiency by the side stream vortex in the prior art. Table 2 shows the influence of the exhaust efficiency by the side vortex in the present invention. The table shows the improved emission efficiency of the present invention.

Propeller and outlet
Side space
Area (m ² ) Percentage of side space relative to outlet area (%) Upstream
Incidence rate
(Low speed section) Upstream
Incidence rate
(High speed section) Remarks 2,355 33 28 21 2,512 29 24 19 2,669 25 21 16 3,376 28 24 18 3,533 25 21 16 3,690 22 19 15 4,553 25 21 16 4,710 23 19 15 4,867 21 18 13 5,024 19 16 12 5,181 18 15 11

Propeller and outlet
Side space
Area (m ² ) Percentage of side space relative to outlet area (%) Upstream
Incidence rate
(Low speed section) Upstream
Incidence rate
(High speed section) Remarks 2,355 33 9 4 2,512 29 8 3 2,669 25 7 3 3,376 28 8 3 3,533 25 7 3 3,690 22 6 3 4,553 25 7 3 4,710 23 6 3 4,867 21 6 2 5,024 19 5 2 5,181 18 5 2

Propeller and outlet
Side space
Area (m ² ) Percentage of side space relative to outlet area (%) Upstream
Improvement rate
(Low speed section) Upstream
Improvement rate
(High speed section) Remarks 2,355 33 19 17 2,512 29 16 15 2,669 25 14 13 3,376 28 16 15 3,533 25 14 13 3,690 22 13 12 4,553 25 14 13 4,710 23 13 12 4,867 21 12 11 5,024 19 11 10 5,181 18 10 9

Here, the lateral space area is calculated as the difference between the outlet area and the propeller area. In addition, the low speed is defined as less than 50 rpm and the high speed is defined as more than 50 rpm, and the upper side stream is defined as the side flow that swirls upward in the space between the outlet and the propeller as the swirling laminar flow swirls upward along the wall of the outlet do.

Hereinafter, the operation of the present invention will be described.

When the drive motor 300 is operated, the rotation shaft 200 connected to the drive shaft of the drive motor 300 rotates. At this time, the plating liquid containing foreign matter (ash, dross) introduced through the inlet 110 of the pump housing 100 is discharged from the discharge port of the pump housing 100 by the rotational force of the propeller 210 of the rotating shaft 200 (120).

In particular, when the propeller 210 rotates, a sidestream is generated at the sidewall of the discharge port 120 around the propeller 210. Since the sidestream is blocked by the blocking jaws 430 of the sidestream prevention plate 400, It is possible to prevent backward flow upward along the sidewall of the discharge port 120. By blocking the direct transfer heat transmitted from the pump housing 100 and the rotary shaft 200c which are immersed in the plating liquid at a high temperature of about 450 degrees, It is possible to prevent the high temperature from being transmitted to the connecting bearing 531 and the motor 300.

As described above, according to the present invention, it is possible to improve the pumping efficiency, to effectively discharge the plating liquid containing foreign matter, and to prevent contamination by the foreign materials in the housing And the high temperature is prevented from being directly transmitted to the bearing and the motor.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited to the disclosed exemplary embodiments. It will also be appreciated that many modifications and variations will be apparent to those skilled in the art without departing from the scope of the present invention.

100: pump housing 110: inlet
120: exhaust port 200: rotating shaft
210: propeller 300: drive motor
400: side plate 500: cooling housing
510: cooling piping 520: exhaust piping
530: Bearing housing 540: Insulation unit
541: sealing cover 542: base plate
543: insulating plate 545: first sealing material
544: Second sealant

Claims (5)

1. A foreign substance discharging actuator for discharging suspended foreign substances on a bath surface in a snout,
A pump housing in which an inlet through which a plating solution containing a foreign substance flows is formed at one side so as to communicate with the inside of the snout and an outlet for discharging the plating solution containing the foreign matter is formed at the other side;
A rotating shaft having a propeller for discharging the plating liquid at its tip and being rotatably installed in the pump housing;
A driving motor fixedly installed on the upper portion of the pump housing to be driven to be connected to the rotating shaft; And
And a side flow prevention plate disposed on the upper side of the propeller to prevent a side stream from rising during rotation of the propeller,
A cooling pipe for enclosing the rotating shaft is provided between the pump housing and the driving motor, a cooling pipe through which a cooling gas flows is inserted into one side of the cooling housing, and a cooling pipe is inserted into the cooling housing through a connecting bearing, And a heat insulating unit is provided between the cooling housing and the pump housing for blocking heat conduction and sealing the interior of the pump housing. delete The method according to claim 1,
Wherein the heat insulating unit includes a sealing cover for enclosing the rotating shaft through a first sealing material, a base plate provided on an outer circumferential surface of the sealing cover, and a heat insulating plate and a second sealing material provided between the base plate and the pump housing It is characterized by the Snout's foreign matter discharge actuator. The method according to claim 1,
The side flow prevention plate includes a support portion for supporting the rotation shaft, a latching protrusion protruding from the upper end in an outer diameter direction on the support portion and fixed to the pump housing, and a protrusion protruding in the center direction from the lower end of the support portion, And a blocking jaw that blocks the foreign matter. The method according to claim 1,
Wherein the rotary shaft includes a connection shaft which is driven and connected to the drive motor via a connection shaft coupling, a rotation shaft provided with a propeller at a lower end thereof, and a heat end flange connecting between the connection shaft and the rotation shaft. Nautical ejection actuator.

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