JP2014114483A - Snout floating scum removal device for molten zinc plating line - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique suppressing dispersion of a discharge flow and reducing quality defects of a steel plate due to the dispersion of the discharge flow in removing scum in a snout by arranging a discharge nozzle and a suction nozzle in the snout to form a discharge flow and using the discharge flow in scum removal.SOLUTION: A discharge nozzle 5 of a snout floating scum removal device is composed of a vertical cylindrical part 8 and a discharge part 9 arranged in the upper end part of the vertical cylindrical part, and the discharge part 9 includes a molten zinc flow inlet 10 connected to the vertical cylindrical part, a box-shaped rectification space 11 rectifying the flow of molten zinc flowing in from the molten zinc flow inlet in the vertically upward direction to in the horizontal direction, a discharge outlet 12 discharging molten zinc toward the inside of the snout in the horizontal direction and a guide space 13 guiding molten zinc from the rectification space to the discharge outlet. The discharge part 9 meets the condition: (the vertical height of the rectification space-the vertical height of the discharge outlet)/the vertical height of the discharge outlet≥0.2.

Description

  The present invention relates to a device for removing floating scum in a snout in a hot dip galvanizing line.

  As shown in FIG. 11, the hot dip galvanizing line includes a cylindrical snout 4 that connects between the reduction annealing furnace 1 and the hot dip zinc pot 3. The snout 4 has a function of immersing the steel strip 2 treated in the reduction annealing furnace 1 in the molten zinc pot 3 while protecting the steel strip 2 in a reducing atmosphere, and one end thereof is the reduction annealing furnace 1. The other end is partially immersed in the molten zinc pot 3, and the inside of the snout 4 is filled with a reducing atmosphere gas.

  In the snout 4, a phenomenon in which zinc evaporated from the surface of the zinc bath condenses and adheres to the inner wall to form powdery scum is unavoidable. If the scum adhering to the inner wall in the snout 4 falls on the bath surface due to vibration or the like and adheres to the steel strip 2, it causes a quality defect. Therefore, conventionally, as shown in FIG. 12, a method of forming a flow on the surface of the zinc bath in the snout 4 and discharging the floating scum floating on the bath surface to the outside of the system has been widely adopted. In Patent Document 1, a discharge nozzle 5 that discharges molten zinc and a suction nozzle 6 that sucks scum together with molten zinc are arranged in the vicinity of the surface of the molten zinc pot in the snout 4 so as to flow on the surface of the zinc bath. Techniques for forming are disclosed. As shown in FIG. 13, the conventional discharge nozzle 5 generally has a simple shape in which the tip of a vertically arranged tubular member is opened in the discharge direction.

  However, when the discharge nozzle 5 as shown in FIG. 13 is used, as shown in FIG. 14, the discharge flow is dispersed inside the bath, and this dispersion of the discharge flow causes a new quality defect. there were. Specifically, when the discharge flow is dispersed in the direction of the inner wall of the snout, the flow velocity near the inner wall of the snout is increased, the scum adhering to the wall surface is peeled off, and the cleanliness of the bath surface is lowered, which causes the quality defect of the steel sheet. There was a problem. In addition, when the discharge flow is dispersed inside the bath and the bath surface undulates, there is a problem that a wavy pattern is generated on the steel sheet, resulting in a quality defect. Furthermore, when the discharge flow is dispersed inside the bath, the bath surface flow velocity is lowered, and there is a problem that the scum is adhered to the steel plate before being discharged, resulting in a quality defect.

  In order to compensate for the decrease in bath surface flow velocity and obtain the desired bath surface flow velocity, it is necessary to increase the discharge flow rate using a large discharge pump, and increasing the discharge flow rate promotes each of the above problems. There were also problems such as vicious circles and increased equipment costs.

JP-A-8-269659

  The object of the present invention is to solve the above-mentioned problems, and to form a discharge flow by providing a discharge nozzle and a suction nozzle in the snout, and to suppress the dispersion of the discharge flow when removing the scum in the snout using this discharge flow. Another object of the present invention is to provide a technique for reducing the quality defect of the steel sheet that has been caused by the dispersion of the discharge flow.

  In the hot dip galvanizing line, the apparatus for removing floating scum in the hot dip galvanizing line of the present invention, which has been made to solve the above-mentioned problems, is near the zinc bath surface in the snout connecting the reduction annealing furnace and the hot dip zinc pot in the hot dip galvanizing line. In the vicinity of both sides of the steel strip passing through the snout, a discharge nozzle that discharges molten zinc and a suction nozzle that sucks scum together with the molten zinc are arranged oppositely to form a flow from the discharge nozzle to the suction nozzle. A device for removing floating scum in a snout that removes scum floating inside, wherein the discharge nozzle includes a vertical tube portion and a discharge portion disposed at an upper end portion of the vertical tube portion. A molten zinc inlet connected to the cylindrical portion, and a box-shaped rectifying space for horizontally rectifying the flow of molten zinc flowing vertically upward from the molten zinc inlet. It has a discharge port that discharges molten zinc horizontally into the snout and a guide space that guides the flow of molten zinc from the rectifying space to the discharge port (vertical height of the rectifying space-vertical height of the discharge port Sa) / vertical height of discharge port ≧ 0.2 is satisfied.

  The invention described in claim 2 is characterized in that, in the apparatus for removing floating scum in the snout in the hot dip galvanizing line according to claim 1, the horizontal distance of the guide space / the directional distance of the rectifying space ≧ 0.2. Is.

  The discharge nozzle is composed of a vertical cylinder part and a discharge part disposed at the upper end of the vertical cylinder part, and the discharge part is connected to the vertical cylinder part and is perpendicular to the molten zinc inlet. A box-shaped rectifying space that rectifies the flow of molten zinc flowing upward upward in the horizontal direction, a discharge port that discharges molten zinc horizontally into the snout, and a flow of molten zinc from the rectifying space to the discharge port By having a guide space for guiding the flow and satisfying (vertical height of rectifying space−vertical height of discharge port) / vertical height of discharge port ≧ 0.2, in the discharge nozzle, The vertical flow of molten zinc flowing in at high speed from the molten zinc inflow port is rectified in the horizontal direction and discharged by colliding with the upper surface of the rectifying space that is higher than the upper end of the discharge port while taking a long flow path. Compared to the prior art, the bath inside the snout table Surface waviness is reduced and the (average) flow velocity in the width direction of the steel sheet is increased. Moreover, by having a guide space, it is possible to guide the discharge flow, and as shown in FIG. 7, dispersion of the discharge flow is suppressed as compared with the conventional technique.

It is a principal part front view of the floating scum removal apparatus in the snout of this invention. It is a front view of a discharge nozzle. It is a front side view of a discharge nozzle. It is a top view of a discharge nozzle. It is a figure (front view of a discharge nozzle) explaining the rectification | straightening effect | action in a discharge nozzle. It is a figure (top view of a discharge nozzle) explaining the rectification | straightening effect | action in a discharge nozzle. It is a figure which shows the flow velocity distribution of a discharge flow in contrast with a prior art and this invention. It is a figure which shows the effect of this invention (reduction of a wave). It is a figure which shows the effect of this invention (inner wall vicinity flow velocity reduction). It is a figure which shows the effect of this invention (average flow velocity increase). It is explanatory drawing of a hot dip galvanizing line. It is a principal part front view of the conventional floating scum removal apparatus in a snout. It is a front view of the conventional discharge nozzle. It is a figure which shows the flow velocity distribution of the conventional discharge flow.

  Preferred embodiments of the present invention are shown below.

As shown in FIG. 11, one end portion of the snout 4 is connected to the reduction annealing furnace 1, and the other end portion is partially immersed in the molten zinc pot 3. The portion immersed in the molten zinc pot 3 of the snout 4 is made of a material (ceramics, heat-resistant steel cast steel product, etc.) having excellent corrosion resistance against zinc. A reducing atmosphere gas (for example, 50% H ₂ -50% N ₂ ) is introduced inside the snout 4.

  The in-snout floating scum removing device of the present invention has a function of forming a flow near the surface of the zinc bath in the snout 4 and discharging the scum generated in the snout 4 out of the system without adhering to the steel strip. Yes, as shown in FIG. 1, it has a discharge nozzle 5 for discharging molten zinc, and a suction nozzle 6 for sucking scum together with molten zinc, and the others are a supply line, a suction line, a pump, etc. (not shown) The configuration is the same as in the prior art.

  As shown in FIG. 14, in the prior art using the discharge nozzle shown in FIG. 13, the discharge flow is dispersed inside the bath, and in particular, a phenomenon is observed in which the flow velocity near the inner wall of the snout increases and the bath surface flow velocity decreases. However, in the present invention, the discharge nozzle 5 is formed in the shape shown in FIGS.

  As shown in FIGS. 2 to 4, the discharge nozzle 5 of the present invention includes a vertical cylinder portion 8 and a discharge portion 9 disposed at the upper end portion of the vertical cylinder portion.

  The discharge part 9 includes a molten zinc inlet 10 connected to the vertical cylinder part 8, and a box-shaped rectifying space 11 that rectifies the flow of molten zinc flowing vertically upward from the molten zinc inlet 10 in the horizontal direction. , Having a discharge port 12 that discharges molten zinc horizontally into the snout 4 and a guide space 13 that guides the flow of molten zinc from the rectifying space 11 to the discharge port 12, as shown in FIG. (Vertical height of rectifying space−vertical height of discharge port) = H2, vertical height of discharge port = H1, horizontal distance of guide space = L1, and direction distance of rectifying space = L2, H2 / H1 The relationship of ≧ 0.2 and L1 / L2 ≧ 0.2 is satisfied. H2 is preferably 10 mm or more because a certain amount of space is required above the rectifying space in order to reliably rectify the flow. The upper limit of H2 is not particularly defined, but if the dimension is too large, stagnation may occur above the discharge unit 9, so 200 mm or less is preferable. Further, L1 is preferably 10 mm or more in order to suppress flow dispersion. The upper limit of L1 is not particularly defined, but if it is too large, there is interference with the steel plate and peripheral devices, so 300 mm or less is preferable. H1 and L2 are appropriately determined according to the amount of molten zinc to be discharged, the size of the vertical cylindrical portion 8, and the like.

  By setting the discharge nozzle 5 to the above configuration, as shown in FIGS. 5 to 6, the vertical flow of molten zinc flowing at high speed from the molten zinc inflow port 10 is caused to flow through the rectifying space 11 and the guide space 13. Rectification in the horizontal direction and discharge can be performed while taking a long flow path, and as shown in FIG. 7, dispersion of the discharge flow can be suppressed as compared with the prior art.

  As a result of verifying the effect of the present invention with a simulation test machine (actual machine 1/2 size), the ripple on the bath surface is reduced as shown in FIG. 8, and the flow velocity near the inner wall of the snout is reduced as shown in FIG. As shown in FIG. 10, it was confirmed that the (average) flow velocity in the width direction of the steel sheet increased.

  Furthermore, when the effect of the present invention was verified by an actual machine test, it was confirmed that the adhesion amount of the bath surface floating scum in the snout to the steel sheet was reduced to about half.

DESCRIPTION OF SYMBOLS 1 Reduction annealing furnace 2 Steel strip 3 Molten zinc pot 4 Snout 5 Discharge nozzle 6 Suction nozzle 8 Vertical cylinder part 9 Discharge part 10 Molten zinc inlet 11 Rectification space 12 Discharge opening 13 Guide space

Claims (2)

In the hot dip galvanizing line, in the vicinity of the surface of the hot dip zinc pot in the snout connecting the reduction annealing furnace and the hot dip zinc pot, in the vicinity of both sides of the steel strip passing through the snout, respectively, a discharge nozzle for discharging hot zinc, and melting An in-snout floating scum removing device that disposes a suction nozzle that sucks scum together with zinc and removes scum floating in the snout while forming a flow from the discharge nozzle to the suction nozzle,
The discharge nozzle is composed of a vertical tube portion and a discharge portion disposed at an upper end portion of the vertical tube portion,
The discharge section includes a molten zinc inlet connected to the vertical cylinder section, a box-shaped rectifying space for horizontally rectifying the flow of molten zinc flowing vertically upward from the molten zinc inlet, and a snout A discharge port that discharges molten zinc in a horizontal direction toward the discharge port, and a guide space that guides the flow of molten zinc from the rectifying space to the discharge port,
A vertical scum removal device in a hot dip galvanizing line that satisfies (vertical height of flow straightening space−vertical height of discharge port) / vertical height of discharge port ≧ 0.2.   2. The apparatus for removing floating scum in a snout in a hot dip galvanizing line according to claim 1, wherein the horizontal distance of the guide space / the direction distance of the rectifying space ≧ 0.2.