KR102175835B1 - Nozzle of distribution plate for fluidized furnace - Google Patents

Abstract

The nozzle is supported by the dispersion plate of the flow path for reducing the spectroscopy, and through which the reducing gas passes, is a nozzle body including an inlet through which the reducing gas is supplied and an outlet narrower than the inlet, and from the inner surface of the nozzle body. And a plurality of protruding lines protruding and extending from the inlet to the outlet.

Description

NOZZLE OF DISTRIBUTION PLATE FOR FLUIDIZED FURNACE}

The present description relates to a nozzle supported on a dispersion plate installed inside a flow path.

In general, in the case of a melt reduction iron making facility that directly uses spectroscope to produce molten iron, it includes a plurality of flow paths for flow reduction treatment of spectroscope.

The flow furnace uses a high-temperature reducing gas supplied from the melting gas furnace to reduce the powdery iron ore, spectrophotometer, to reduced iron.

The flow path includes a dispersion plate in which a plurality of nozzles through which the reducing gas passes are supported by being located at the lower side of the flow path. The high-temperature reducing gas passes through the nozzles of the flow path dispersion plate and fluidizes the spectroscopy charged to the upper side of the flow path to reduce the spectroscopy to powdered reduced iron.

However, the conventional nozzle of the flow path dispersion plate has a problem in that the adhesive dust contained in the reducing gas is attached to the inner surface of the nozzle, and the outlet of the nozzle is narrowed or blocked.

An embodiment is to provide a nozzle of a flow path dispersion plate that improves the flow reduction efficiency of the flow path by suppressing adhesion of adhesive dust contained in the reducing gas to the inner surface.

One side is a nozzle that is supported by a dispersion plate of a flow path for reducing the spectroscopy and through which the reducing gas passes, wherein the nozzle main body includes an inlet through which the reducing gas is supplied and an outlet narrower than the inlet, and the It provides a nozzle of the flow path distribution plate including a plurality of protruding lines protruding from the inner surface of the nozzle body and extending from the inlet to the outlet.

The plurality of protruding lines may spirally extend along the inner surface.

The volume of the plurality of protruding lines may decrease from the inlet to the outlet.

Each of the plurality of protruding lines includes two inclined surfaces in contact with each other, and the two inclined surfaces may have different inclinations with respect to the inner surface of the nozzle body.

The plurality of protruding lines may include only a first protruding line, a second protruding line, and a third protruding line separated from each other on the inner surface of the nozzle body and extending from the inlet to the outlet.

Each of the first protruding line, the second protruding line, and the third protruding line may spirally extend along the inner surface.

The inlet and the outlet are circular, and at each of the inlet and the outlet, between the first protruding line and the second protruding line, between the second protruding line and the third protruding line, and the third protruding line and the third protruding line. 1 Between the protruding lines may have a central angle of 120 degrees.

Each of the first protruding line, the second protruding line, and the third protruding line may have a smaller width from the inlet to the outlet.

The dispersion plate includes a through hole in which a nozzle holder is installed, and the nozzle further comprises a nozzle flange extending from the outlet and mounted on the nozzle holder.

According to an embodiment, there is provided a nozzle of a flow path dispersion plate for improving flow reduction efficiency of the flow path by suppressing adhesion of adhesive dust contained in the reducing gas to the inner surface.

1 is a view showing a melt reduction iron-making facility including a nozzle of a flow path distribution plate according to an embodiment.
FIG. 2 is a cross-sectional view showing a nozzle of a flow path distribution plate supported by the dispersion plate shown in FIG. 1.
3 is a perspective view showing a nozzle of a flow path distribution plate according to an embodiment.
4 is a view as viewed from an inlet of a nozzle of a flow path distribution plate according to an embodiment.
5 is a cross-sectional view showing the effect of a nozzle of a flow path distribution plate according to an embodiment.
6 is a cross-sectional view showing a flow path including a nozzle of a flow path distribution plate according to an embodiment.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present invention. The present invention may be implemented in various different forms, and is not limited to the embodiments described herein.

In order to clearly describe the present invention, parts irrelevant to the description have been omitted, and the same reference numerals are assigned to the same or similar components throughout the specification.

In addition, throughout the specification, when a part "includes" a certain component, it means that other components may be further included rather than excluding other components unless otherwise stated.

Hereinafter, a nozzle of a flow path dispersion plate according to an embodiment will be described with reference to FIGS. 1 to 4. The nozzle of the flow path dispersion plate may be a nozzle supported by the flow path dispersion plate included in the melt reduction iron making facility, but is not limited thereto.

1 is a view showing a melting reduction iron-making facility including a nozzle of a flow path distribution plate according to an embodiment.

The melt-reduction iron-making facility includes a plurality of flow paths 20 for reducing the spectroscopic 10 to powdered reduced iron, a compacting device 30 for compressing the powdered reduced iron to produce a compacted material, and a melted gas furnace 40. The spectroscope 10 is charged into the flow paths 20, and the reduced reduced iron reduced from the flow paths 20 is manufactured as a compacted material in the compacting device 30 and supplied to the molten gas furnace 40 together with the coal briquettes. It can be made of molten iron. The reducing gas generated from the molten oil gas furnace 40 may be supplied to the flow paths 20.

In FIG. 1, the plurality of flow paths 20 are three sequentially connected, but the present invention is not limited thereto, and the plurality of flow paths 20 may be one, two, or four or more.

On the other hand, the melt reduction iron-making facility is not limited to the structure shown in FIG. 1, and may include various known configurations.

A dispersion plate 21 is located under the interior of the flow path 20.

The dispersion plate 21 distributes and sprays the reducing gas introduced into the lower portion of the flow path 20 by the spectroscope 10 positioned above the dispersion plate 21. The dispersion plate 21 may have a structure capable of supporting the weight of the spectroscope 10 forming a fluidized bed.

The dispersing plate 21 supports nozzles 100 of a plurality of flow path dispersing plates through which the reducing gas injected into the lower part of the flow path 20 passes through the upper part of the dispersing plate 21.

FIG. 2 is a cross-sectional view showing a nozzle of a flow path distribution plate supported by the dispersion plate shown in FIG. 1.

Referring to FIG. 2, the nozzle 100 of the flow path distribution plate is mounted on the nozzle holder 22 corresponding to the through hole in which the nozzle holder 22 is installed. The nozzle 100 of the flow path distribution plate may be mounted on the nozzle holder 22 using a coupling member such as a bolt. The nozzle holder 22 may have various known shapes.

The nozzle 100 of the flow path dispersing plate passes the reducing gas RG supplied from the lower portion of the nozzle holder 22 installed in the through hole of the dispersing plate 21 to the upper part of the dispersing plate 21 while passing the reducing gas RG ) Is transformed into a tornado shape with an increased flow velocity, and the dust is prevented from adhering to the inner surface 113 of the nozzle 100 of the flow path dispersion plate by using centrifugal force, and at the same time, the spectral is transferred to the top of the nozzle 100 of the flow path dispersion plate. It suppresses sticking.

The nozzle 100 of the flow path distribution plate includes a nozzle body 110, a plurality of protruding lines 120, and a nozzle flange 130.

3 is a perspective view showing a nozzle of a flow path distribution plate according to an embodiment. 3(A) is a perspective view of the nozzle of the flow path distribution plate as viewed from one side, and (B) is a perspective view of the nozzle of the flow path distribution plate with a partially cut-off view as viewed from one side.

2 and 3, the nozzle body 110 has a conical shape and forms a passage through which the reducing gas RG passes. The nozzle body 110 includes an inlet 111, an outlet 112, and an inner surface 113.

The inlet 111 is a part to which the reducing gas RG is supplied.

The outlet 112 is a part from which the reducing gas RG is discharged. The outlet 112 has a narrow area compared to the inlet 111.

Since the outlet 112 has a narrower area than the inlet 111, the reducing gas RG supplied to the inlet 111 is discharged through the outlet 112, thereby increasing the flow rate.

The inner surface 113 extends from the inlet 111 to the outlet 112 and has a conical shape. The inner surface 113 forms a passage through which the reducing gas RG passes. A plurality of protruding lines 120 are formed on the inner surface 113.

The plurality of protruding lines 120 protrude from the inner surface 113 and extend from the inlet 111 to the outlet 112.

The plurality of protruding lines 120 spirally extend along the inner surface 113.

As a result, the reducing gas (RG) supplied to the inlet 111 is transformed into a tornado with an increased flow rate due to the protruding lines 120 as it passes through the outlet 112 along the inner surface 113 and uses centrifugal force to the inner surface. The dust attached to (113) is separated from the inner surface (113). That is, adhesion of dust to the inner surface 113 of the nozzle 100 of the flow path dispersion plate is suppressed by the plurality of protruding lines 120, and the spectra are fixed to the top of the nozzle 100 of the flow path dispersion plate. Is suppressed.

In addition, the volume of the plurality of protruding lines 120 decreases from the inlet 111 to the outlet 112.

As a result, collision between the reducing gases RG in the form of a tornado having an increased flow velocity passing through the outlet 112 is minimized.

In addition, each of the plurality of protruding lines 120 includes a first inclined surface IS1 and a second inclined surface IS2 that are two inclined surfaces in contact with each other, and the first inclined surface IS1 and the second inclined surface ( IS2) has different inclinations with respect to the inner surface 113 of the nozzle body 110. For example, the first inclined surface IS1 corresponding to the convex portion of each of the plurality of protruding lines 120 extending in a spiral shape has a larger inclination with respect to the inner surface 113 than the second inclined surface IS2 corresponding to the concave portion. Have.

As a result, the reducing gas RG supplied to the inlet 111 is passed along the inner surface 113 to the outlet 112 in the form of a tornado in which the flow velocity is increased by the second inclined surface IS2 of the protruding lines 120. Transformed.

Meanwhile, in another embodiment, the plurality of protruding lines 120 may have an arc shape, and the first inclined surface IS1 corresponding to the convex portion of each of the plurality of protruding lines 120 is a first inclined surface IS1 corresponding to the concave portion. 2 The radius of curvature may be larger than that of the inclined surface IS2.

In addition, the plurality of protruding lines 120 have a protruding shape rather than a concave shape, thereby suppressing the attachment of dust to the protruding lines 120 themselves. The plurality of protruding lines 120 have a significantly different configuration from a recessed groove in which dust is easily attached.

Meanwhile, in another embodiment, a surface treatment layer for preventing dust adhesion may be positioned on the inner surface 113 of the nozzle body 110. As an example, the surface treatment layer may be a hydrophobic treatment layer, but it is not limited thereto, and may be a surface treatment layer including various known materials as long as dust adhesion can be prevented.

4 is a view as viewed from an inlet of a nozzle of a flow path distribution plate according to an embodiment.

3 and 4, the plurality of protruding lines 120 of the nozzle 100 of the flow path distribution plate are spaced apart from each other on the inner surface 113 of the nozzle body 110, and the outlet 112 from the inlet 111 It includes only the first protruding line 121, the second protruding line 122, and the third protruding line 123 that are extended to each other.

Each of the first protruding line 121, the second protruding line 122, and the third protruding line 123 spirally extends along the inner surface 113.

As a result, the reducing gas RG supplied to the inlet 111 passes through the outlet 112 along the inner surface 113 and extends in a spiral shape, the first protruding line 121, the second protruding line 122, and 3 Due to the protruding line 123, it is transformed into a tornado shape with an increased flow velocity, and the dust adhered to the inner surface 113 is separated from the inner surface 113 using centrifugal force. That is, dust is suppressed from adhering to the inner surface 113 of the nozzle 100 of the flow path distribution plate by the first protruding line 121, the second protruding line 122, and the third protruding line 123. At the same time, the spectroscopy is suppressed from sticking to the top of the nozzle 100 of the flow path dispersion plate.

In addition, each of the first protruding line 121, the second protruding line 122, and the third protruding line 123 has a smaller width from the inlet 111 to the outlet 112, and has a circular inlet 111 and At each of the circular outlets 112, between the first protruding line 121 and the second protruding line 122, between the second protruding line 122 and the third protruding line 123, and the third protruding line 123 And the first protruding line 121 has a central angle of 120 degrees.

In addition, in each of the first protruding line 121, the second protruding line 122, and the third protruding line 123, one part located at the inlet 111 and the other part located at the outlet 112 are virtually straight. It is located on the top.

Accordingly, collision between the reducing gases RG in the form of a tornado whose flow velocity is increased by the first protruding line 121, the second protruding line 122, and the third protruding line 123 is minimized.

When the number of the plurality of protruding lines 120 is 4 or more, the cross-sectional area of the inside of the nozzle 100 of the flow path dispersing plate is small, so that when the reducing gas RG passes through the nozzle 100 of the flow path dispersing plate, Resistance is applied to the dispersion plate 21, and a phenomenon in which the reducing gas RG is finely dispersed may occur, thereby causing an obstacle to the flow rate of the reducing gas RG and the fluidization of the spectrum.

However, the nozzle 100 of the flow path distribution plate according to an embodiment includes only the first protruding line 121, the second protruding line 122, and the third protruding line 123, so that the reducing gas RG is After the reducing gas (RG) is passed from the lower part of the dispersing plate 21 to the upper part of the dispersing plate 21 by suppressing the phenomenon of dispersion, the reducing gas in a tornado shape is also used between the nozzles 100 of the adjacent flow path dispersing plate. By widening the gas distribution of RG), the spectral fluidization efficiency can be improved.

Referring back to FIG. 2, the nozzle flange 130 extends from the outlet 112 of the nozzle body 110 and is mounted on the nozzle holder 22 by a coupling member such as a bolt.

Hereinafter, the effect of the nozzle of the flow path dispersion plate according to an embodiment will be described with reference to FIGS. 5 and 6.

5 is a cross-sectional view showing the effect of a nozzle of a flow path distribution plate according to an embodiment. 5A is a cross-sectional view showing a nozzle of a conventional flow path distribution plate, and (B) is a cross-sectional view showing a nozzle of a flow path distribution plate according to an embodiment.

5A and 5B, the nozzle 5 of the conventional flow path dispersion plate increases only the flow velocity of the reducing gas RG, while the nozzle of the flow path dispersion plate according to an embodiment ( 100) includes a plurality of protruding lines 120, so that the reducing gas RG supplied to the inlet 111 is transformed into a tornado with an increased flow rate and passed through the outlet 112, the reducing gas RG The dust attached to the inner surface 113 is separated from the inner surface 113 using the centrifugal force of.

That is, the flow reduction efficiency of the flow path by suppressing the adhesion of dust to the inner surface 113 of the nozzle 100 of the flow path dispersing plate and preventing spectroscopy from sticking to the top of the nozzle 100 of the flow path dispersing plate. The nozzle 100 of the flow path dispersion plate is provided to improve the.

6 is a cross-sectional view showing a flow path including a nozzle of a flow path distribution plate according to an embodiment.

6, the nozzle 100 of the flow path dispersion plate supported by the dispersion plate 21 of the flow path 20 suppresses dust from adhering to the inner surface of the nozzle 100 of the flow path dispersion plate and flows By suppressing the adhesion of the spectroscope 10 to the top of the nozzle 100 of the furnace dispersion plate, an increase in the differential pressure (ΔP) between the upper and lower portions of the dispersion plate 21 inside the flow path 20 is minimized. , The dispersion plate 21 is prevented from being damaged by the differential pressure ΔP, and the fluidization efficiency of the spectroscope 10 is improved.

That is, by minimizing an increase in the differential pressure (ΔP) between the upper and lower portions of the dispersion plate 21 inside the flow path 20, the dispersion plate 21 inside the flow path 20 according to the increase of the differential pressure (△P) A nozzle 100 of a flow path dispersion plate is provided for suppressing breakage and improving the fluidization efficiency of the spectroscope 10 inside the flow path 20.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention defined in the following claims are also present. It belongs to the scope of rights of

The flow path 20, the dispersion plate 21, the nozzle 100 of the flow path dispersion plate, the nozzle body 110, the protruding line 120, the first protruding line 121, the second protruding line 122, 3rd protruding line 123

Claims (9)

In the nozzle supported by the dispersion plate of the flow path for reducing the spectroscopy and passing the reducing gas,
A nozzle body including an inlet through which the reducing gas is supplied and an outlet through which the reducing gas is discharged; And
A plurality of protruding lines protruding from the inner surface of the nozzle body and extending from the inlet to the outlet
Including,
The plurality of protruding lines include only a first protruding line, a second protruding line, and a third protruding line spaced apart from each other on the inner surface of the nozzle body and extending from the inlet to the outlet,
Each of the first protruding line, the second protruding line, and the third protruding line extends spirally along the inner surface,
The inlet and the outlet are circular,
At each of the inlet and the outlet, a central angle of 120 degrees between the first protruding line and the second protruding line, between the second protruding line and the third protruding line, and between the third protruding line and the first protruding line The branch is the nozzle of the flow path distribution plate. delete In claim 1,
The plurality of protruding lines are nozzles of the flow path distribution plate whose volume decreases from the inlet to the outlet. In claim 1,
Each of the plurality of protruding lines includes two inclined surfaces in contact with each other,
The two inclined surfaces are nozzles of the flow path distribution plate having different inclinations with respect to the inner surface of the nozzle body. In claim 1,
A nozzle of a flow path distribution plate in which a surface treatment layer is located on an inner surface of the nozzle body. In clause 5,
The surface treatment layer is a hydrophobic treatment layer, the nozzle of the flow path dispersion plate. delete In claim 1,
Each of the first protruding line, the second protruding line, and the third protruding line has a smaller width from the inlet to the outlet. In claim 1,
The dispersion plate includes a through hole in which a nozzle holder is installed,
The nozzle of the flow path distribution plate further comprises a nozzle flange extended from the outlet and mounted on the nozzle holder.

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