KR200265549Y1 - Guided Canopy Hood - Google Patents

Abstract

The present invention relates to an internal ventilation of a plant, and more particularly, a canopy installed at an upper portion of a dust or toxic gas generating device or a furnace to efficiently remove dust or toxic gas generated therefrom. It's about the hood.

Therefore, the present invention, the canopy hood for sucking contaminants on the upper part of the furnace is installed by a predetermined distance spaced apart, and moves the raw material while moving along the crane rail installed between the furnace and the canopy hood In the internal ventilation system comprising a crane bogie to charge into,

It is formed so as to surround the outer periphery of the crane bogie, disposed at the bottom facing the top of the furnace to induce the inflow of pollutants and disposed at the top facing the bottom of the canopy hood on the bottom opening A body portion having a top opening which induces the discharge of pollutants introduced through; And it provides a guide duct type canopy hood comprising a connection portion formed inside the body portion so that the crane cart is mounted therein.

Description

Induction duct type canopy hood {Guided Canopy Hood}

The present invention relates to an internal ventilation of a plant, and more particularly, a canopy installed at an upper portion of a dust or toxic gas generating device or a furnace to efficiently remove dust or toxic gas generated therefrom. It's about the hood.

Such a hood is generally applied to a steelmaking process, which generally refers to a process of making iron by removing iron from iron ore by melting iron ore and burning coke.

In the steelmaking process, raw materials such as iron ore, coke, limestone, and the like are charged into a furnace using a step transported by a crane, and various dusts and toxic gases are generated at this time.

In addition, such a problem occurs not only in the above-described steelmaking process, but also in an electric furnace or a melting furnace of a steelmaking process or a plating process, and similar ventilation problems occur in raw material unloading and firebrick dismantling plants.

Conventionally, steel mills install various canopy hoods at the top of the furnace in order to forcibly treat such dusts or toxic gases, suck in pollutants, and send them to an electric dust collector for treatment.

However, a canopy hood that sucks in large amounts of pollutants generated during crane operation is located in the upper part of the crane in most cases, and thus the crane trolley blocks the flow path of these pollutants, which is a major obstacle to improving ventilation efficiency.

FIG. 5 is a view showing a schematic structure of a conventional factory internal ventilation system, and FIG. 6 is a view showing flow visualization of the upper flow of a conventional electric furnace using an experimental model.

As shown in FIG. 5, the direction (B) of the flow is changed due to the crane bogie, in which dust and toxic gases rising from the electric furnace are located at the upper part, and thus, the contaminants are properly sucked into the canopy hood 30. Even if the shape of the hood is modified in various ways at the top of the furnace 10, it is difficult to effectively remove dust or toxic gas without removing the crane bogie 20 located at the bottom of the hood. .

Recently, there have been attempts to increase the suction power of the canopy hood by increasing the power of the blower, but the maintenance cost is increased in proportion to the increase in power, but the suction efficiency does not increase so much that there is a problem that it is not economically or process efficient.

The present invention was devised to solve the problems as described above, the purpose of which is to be installed in the crane device to effectively suck in dust and toxic gas generated in the furnace while maintaining the conventional canopy hood and crane device as it is It is to provide an induction duct type canopy hood.

1 is a schematic view of the factory ventilation system installed induction duct type canopy hood according to the present invention.

2 is a plan view illustrating an induction duct type canopy hood according to an embodiment of the present invention.

3 is a plan view illustrating an induction duct type canopy hood according to another embodiment of the present invention.

4 is a flow visualization diagram of the experimental model to which the induction duct type canopy hood according to the present invention.

5 is a view showing a schematic structure of a conventional factory internal ventilation system.

6 is a flow visualization diagram of a conventional electric furnace upper flow using an experimental model.

* Description of the symbols for the main parts of the drawings *

10: furnace 20: induction duct type canopy hood

20a: body portion 20b: connection portion

20c: lower opening 20d: upper opening

20e: rail groove 30: canopy hood

40: crane bogie 50: crane rail

A, B: Pollutant Flow Pathway

In order to achieve the above object, the present invention, the canopy hood for sucking contaminants on the upper part of the furnace is installed by a predetermined distance, and move along the crane rail installed between the furnace and the canopy hood. In the internal ventilation system including a crane bogie to transfer the raw material into the furnace while feeding,

It surrounds the outer circumference of the crane bogie, disposed at the bottom facing the top of the furnace to induce the inflow of contaminants and disposed at the top facing the bottom of the canopy hood and introduced through the bottom opening. It provides a guide duct type canopy hood comprising a body portion having a top opening for inducing the discharge of pollutants, and a connection portion formed inside the body portion so that the crane cart is mounted therein.

Preferably, the body portion is made smaller in area than that of the lower opening.

Here, the horizontal cross section of the body portion may be a quadrangle, and the shapes of the lower and upper openings may be formed in a quadrangle.

Furthermore, when half of the length of one side of the upper opening is d ₁ , and half of the length of one side of the lower opening is d ₂ , , It is desirable to satisfy R i, where R is the top radius of the furnace and D is the length of one side of the crane bogie.

In addition, the horizontal cross section of the body portion and the shape of the lower opening and the upper opening can be manufactured in a circular shape.

At this time, if the radius of the upper opening is r ₁ and the radius of the lower opening is r ₂ , , It is preferable to satisfy R i, where R is the top radius of the furnace and D is the length of one side of the crane bogie.

On the other hand, it is preferable to form a rail groove in the lower end of the body portion so that the crane rail can pass.

The present invention also comprises a furnace in which the raw material is charged and dissolved therein; A canopy hood spaced apart by a predetermined distance to inhale contaminants on top of the furnace; A crane bogie for transferring raw materials and charging into the furnace while moving along a crane rail installed between the furnace and the canopy hood; And a bottom opening which is formed to surround an outer circumference of the crane bogie, and is disposed at a bottom thereof to face the top of the furnace to induce the inflow of contaminants, and is disposed to face the bottom of the canopy hood at the top thereof. An internal ventilation system including an induction duct type canopy hood including a body part having a top opening to induce discharge of contaminants introduced through the connection, and a connection part formed inside the body part so that the crane cart is mounted therein; to provide.

Hereinafter, with reference to the accompanying drawings illustrating a preferred embodiment of the present invention.

1 is a schematic view of the factory ventilation system installed induction duct type canopy hood according to the present invention.

As shown in FIG. 1, a crane rail 50 is positioned on top of the furnace 10, and a crane bogie 40 is placed on the crane rail 50, on which a canopy hood 30 is placed. It is installed spaced apart by a predetermined distance. In addition, the induction duct type canopy hood 20 is installed in connection with the crane cart 40 so as to surround the outer periphery of the crane cart 40.

The induction duct type canopy hood 20 is opposite to the top of the furnace 10 at the bottom thereof to induce the inflow of contaminants and to the bottom opening 20c and the top of the canopy hood 30 opposite to the bottom. A body portion 20a having an upper opening portion 20d arranged to induce discharge of contaminants introduced through the lower opening portion 20c, and a crane cart 40 may be housed inside the body portion 20a. It is made of a connecting portion 20b is formed so that the dust or toxic gas generated in the furnace 10 is guided to the canopy hood 30 in the direction of the arrow (A).

In this way, the flow of dust or toxic gas generated from the blast furnace or the electric furnace hits the lower end of the crane cart 40 again bypasses the crane and naturally moves upward along the inner wall of the induction duct type canopy hood 20. The mechanism allows the contaminants to be effectively sucked into the canopy hood 30 without dispersing over the factory building.

It is preferable that the body portion of the induction duct type canopy hood 20 is formed to have an area of the upper opening 20d smaller than that of the lower opening 20c so as to increase the suction efficiency.

In addition, the connection portion 20b may be connected to the crane cart 40 by using welding or other conventional coupling means.

On the other hand, the crane bogie 40 is to move along the crane rail 50 to transfer the raw material to charge into the furnace 10, the canopy hood 30 is made of a funnel shape, this funnel-shaped The large-diameter portion is disposed opposite the upper opening portion 20d of the induction duct type canopy hood 20 and the small-diameter portion communicates with an electrostatic precipitator (not shown) or outside the building, and is generated in the furnace 10 to generate the induction duct. Inhaled dust or toxic gas induced by the type canopy hood 20 serves to discharge it to the electric dust collector (not shown) or outside the building.

2 is a plan view illustrating an induction duct type canopy hood according to an embodiment of the present invention when two rails are provided.

As shown in FIG. 2, the induction duct type canopy hood 20 may be manufactured such that the horizontal cross section of the body portion 20a, the lower opening 20c, and the upper opening 20d are rectangular, preferably square. It is to be made to be.

At this time, the preferable correlation of the upper opening part 20d, the lower opening part 20c, the crane trolley | bogie 40, and a furnace is as follows.

That is, when half of the length of one side of the upper opening 20d is d ₁ , and half of the length of the lower side of the lower opening 20c is d ₂ , , Where R is defined as the top section radius of the furnace, and D is defined as the length of one side of the crane bogie 40.

On the other hand, the induction duct-type canopy hood 20 is mounted on the crane bogie 40 to move on the crane rail 50 together, so that the portion of the crane rail 50 passes through the lower end of the body portion (20a) As shown in FIG. 2, the rail groove 20e may be formed. In the case of the trolley | bogie 40 which moves by one rail, there will be one rail groove.

3 is a plan view illustrating an induction duct type canopy hood according to another embodiment of the present invention.

As shown in FIG. 3, the induction duct-type canopy hood 60 may be manufactured so that the horizontal cross section of the body portion 60a, the lower opening 60c, and the upper opening 60d are circular.

At this time, the preferable correlation between the upper opening 60d, the lower opening 60c, the crane trolley 40, and the furnace is as follows.

That is, when the radius of the upper opening 60d is r ₁ and the radius of the lower opening 60c is r ₂ , , Where R is defined as the top radius of the furnace and D is defined as the length of one side of the crane bogie 40.

On the other hand, the induction duct-type canopy hood 60 is mounted on the crane bogie 40 to move on the crane rail 50 together, so that the portion of the crane rail 50 passes through the lower end of the body portion (60a) As shown in FIG. 3, the rail groove 60e may be formed, and a portion of the crane pilot's field of view may be installed using a tempered glass or the like.

As described above, the horizontal section, the upper opening, and the lower opening of the induction duct type canopy hood body portion are preferably manufactured to be rectangular or circular, but in various shapes such as polygonal or oval according to the internal conditions of the factory to be ventilated. It is also possible to produce.

4 is a flow visualization diagram of the experimental model to which the induction duct type canopy hood according to the present invention.

In comparison with FIG. 6, which is a flow visualization diagram of a conventional electric furnace upper flow, induction duct type canopy hood 20 does not spread dust or toxic gas generated in the furnace 10 outside the canopy hood 30. It can be seen from Figure 4 that the suction is efficiently through.

The above system can be applied by variously changing the shape and size in industrial fields such as raw material yard, dismantling plant, heavy industrial company's workshop as well as blast furnace or electric furnace of actual steel mill.

In addition, while the preferred embodiment of the present invention has been described through the above, the present invention is not limited to this, and it is possible to carry out various modifications within the scope of the utility model registration claims and the detailed description of the invention and the accompanying drawings. Of course, this also belongs to the scope of the present invention.

As described above, according to the induction duct type canopy hood according to the present invention, the flow that hits the crane naturally flows into the upper canopy hood, and the suction efficiency of the canopy hood is improved by suppressing the flow that leaks outwards and thus the factory It is effective to improve working environment.

In addition, since the induction duct type canopy hood according to the present invention can be mounted on the crane bogie while maintaining the conventional canopy hood and the crane device, the facility investment cost can be reduced.

Claims (9)

A canopy hood for suctioning contaminants at an upper part of the furnace is installed at a predetermined distance apart, and moves along a crane rail installed between the furnace and the canopy hood while transferring raw materials and charging the tank into the furnace. In the internal ventilation system comprising: It is formed so as to surround the outer periphery of the crane bogie, disposed at the bottom facing the top of the furnace to induce the inflow of pollutants and disposed at the top facing the bottom of the canopy hood on the bottom opening A body portion having a top opening which induces the discharge of pollutants introduced through; And Connection portion formed inside the body portion so that the crane cart is mounted therein Induction duct-type canopy hood comprising a. The method of claim 1, And the body portion has an area of an upper opening smaller than an area of the lower opening. The method of claim 1, The body portion is a horizontal cross-section is rectangular, the guide duct type canopy hood, characterized in that the shape of the lower opening and the upper opening is rectangular. The method of claim 3, wherein The body portion of the guide duct type canopy hood, characterized in that the upper opening and the lower opening satisfies the following conditions. , Here, d ₁ is half of the length of one side of the upper opening, d ₂ is half of the length of one side of the lower opening, R is the radius of the top surface of the furnace, and D represents the length of one side of the crane bogie. The method of claim 1, The body portion has a circular horizontal cross section, the guide duct type canopy hood, characterized in that the shape of the lower opening and the upper opening is circular. The method of claim 5, The body portion of the guide duct type canopy hood, characterized in that the upper opening and the lower opening satisfies the following conditions. , Here, r ₁ is the radius of the top opening, r ₂ is the radius of the bottom opening, R is the top surface radius of the furnace, and D is the length of one side of the crane bogie. The method according to any one of claims 1, 3 and 5, Induction duct-type canopy hood, characterized in that the rail groove is formed so that the crane rail passes through the body portion. A furnace in which raw materials are charged and dissolved inside; A canopy hood spaced apart by a predetermined distance to inhale contaminants on the top of the furnace; A crane bogie for transferring raw materials and charging into the furnace while moving along a crane rail installed between the furnace and the canopy hood; And It is formed so as to surround the outer periphery of the crane bogie, disposed at the bottom facing the top of the furnace to induce the inflow of pollutants and disposed at the top facing the bottom of the canopy hood on the bottom opening Induction duct type canopy hood including a body portion having a top opening for inducing the discharge of pollutants introduced through, and a connection portion formed inside the body portion so that the crane cart is mounted therein Internal ventilation system comprising a. The method of claim 8, The furnace is an internal ventilation system, characterized in that the electric furnace or blast furnace.