KR101435082B1 - Apparatus for equalizing air blow in checker chamber of hot blast furnace - Google Patents

Abstract

The present invention relates to an apparatus for equalizing an air flow in a hot air furnace regulating chamber, and more particularly, to an apparatus for equalizing an air in a hot air furnace regulating chamber provided in a lower space of a hot air furnace regulating chamber, And an air blowing equalizing portion provided in the blowing air inflow portion and blowing toward the lower side of the regenerating chamber to uniformly maintain air blowing in the lower space of the regenerating chamber. Accordingly, the present invention provides various types of hot air uniform parts in the hot air inflow part formed in the lower part of the hot air furnace heat storage room, thereby generating turbulent flow in the blowing air, uniformly distributing the blown air into the internal space of the heat storage room, So that the heat efficiency of the entire hot air path is increased.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an air blow-

The present invention relates to an apparatus for blowing airflow equalization in a hot air furnace heat storage chamber, and more particularly, to an apparatus for blowing out air in a hot air furnace heat storage chamber installed in a lower space of a hot air furnace heat keeping chamber to introduce air into a lower space.

Generally, steel mills are equipped with hot air ducts for supplying hot air at the time of blast furnace operation. Such hot wind furnace is a facility for producing high-temperature hot wind which burns coke in a blast furnace producing pig iron to reduce iron ore.

In addition, the hot air furnace is divided into an internal combustion type and an external combustion type depending on the position of the combustion chamber, and a dome combustion type. Particularly, the internal combustion type hot air furnace has a cylindrical structure and is configured to divide the combustion chamber and the heat storage chamber.

Fig. 1 is a schematic view showing a conventional hot air furnace, Fig. 2 is a thermal distribution diagram showing uneven heat distribution in a conventional hot air furnace regenerating chamber, and Fig. 3 is an enlarged view showing a conventional hot air furnace regenerating chamber.

As shown in FIGS. 1 to 3, the conventional hot air furnace 100 has a structure in which a fuel gas such as BFG (Blast Furnace Gas), COG (Coke Oven Gas), and the like generated during operation of a blast furnace or a coke oven A combustion chamber 130 including a combustion space 131 where the fuel gas supplied from the burner unit 140 is combusted and a hot air outlet 132 for supplying hot air to the blast furnace; And a regenerative chamber 110 for storing the heat generated in the combustion process.

In the burner unit 140, the fuel gas and air are introduced into the burner 141 through the gas inlet 142 and the air inlet 143, and are burned. The combustion gas moving from the combustion chamber 130 to the heat storage chamber 110 And is discharged to the outside through the communication.

The heat storage chamber 110 is provided with a heat accumulation checker blade 111 for accumulating heat in the heat storage chamber so as to supply hot air of about 1250 DEG C to the blast furnace. A lower space 112 in which a support portion and a support portion are installed and a blowing inlet 113 through which low-temperature air flows are formed on one side of the lower space.

The hot air furnace 100 receives the heat through the blowing air of about 240 ° C. to the refractory of the checker burner 111 of the heat accumulating chamber 110 in which the heat is accumulated and supplies the hot air of about 1250 ° C. to the blast furnace.

In this hot-air furnace 100, the heat accumulating checker burner 111 has a temperature distribution of 400 ° C to 1,450 ° C in the height direction, and the low temperature blowing air of about 250 ° C receives heat from the heat accumulator checker burner 111, ° C or more.

2, the conventional hot-air furnace regenerating chamber 110 has a lower space 112 in which a checker knee for supporting a lower portion of the heat accumulating checker knee 111 and a support portion are provided, There is a problem in that it is difficult to uniformly distribute the blowing air to the upper portion of the heat accumulation checker blade 111 on the upper side.

In addition, due to uneven distribution of the blowing air inside the regenerator 110, heat is not uniformly supplied from the regenerator checker 111 and the heat efficiency of the hot air is lowered.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above conventional problems, and it is an object of the present invention to provide an air conditioner that induces a turbulent flow in blowing air to uniformly distribute the blowing air to the inner space of the heat storage chamber so that heat transfer is uniformly transmitted, It is possible to reduce the operation cost and the investment cost by reducing the quantity of the checker duct and the refractory of the heat storage chamber and to reduce the cost of the ventilation air blown to the lower portion of the heat storage chamber, And an object of the present invention is to provide an apparatus for equalizing the blowing air of the apparatus.

According to an aspect of the present invention, there is provided an apparatus for blowing air into a hot air storage room provided in a lower space of a hot air storage room, the apparatus comprising: a blowing inlet formed at a lower portion of the hot air storage room to receive air; And an air blowing equalizing unit installed in the blowing inlet and blowing to the lower side of the regenerating chamber to uniformly maintain air blowing in the lower space of the regenerating chamber.

The airflow equalizing section of the present invention includes an air blowing insertion tube inserted into the air blowing inlet to blow downward into a space below the regenerator and having a tip bent downward.

The blowing equalizing portion of the present invention includes a blowing vane provided with a plurality of guide plates at predetermined angles in the blowing inlet so as to blow downwardly in a lower space of the heat storage chamber.

The airflow equalizing portion of the present invention includes a blowing inlet pipe having a tip end downwardly inclined at a predetermined angle to the blowing inlet portion so as to slant downwardly in the lower space of the regenerating chamber.

The blowing-equal portion of the present invention includes a blowing baffle provided at an opposite portion of the blowing inlet portion to blow down the blowing air introduced into the lower space of the regenerating chamber downwardly at a predetermined angle.

As described above, according to the present invention, since various types of hot air uniform parts are provided in the hot air inflow part formed in the lower part of the hot air furnace heat storage room, turbulent flow is induced in the blowing air to uniformly distribute the blowing air to the inner space of the heat storage room So that the heat transfer is uniformly transmitted, thereby increasing the thermal efficiency of the entire hot air path.

In addition, since the blowing air is uniformly distributed by the hot air cracking portion inside the hot air storage room, the thermal efficiency of the hot air path is increased to reduce the operation cost, and the amount of checker fins and refractories in the heat storage room can be reduced to reduce the investment cost .

The blowing air is blown downward from the lower central portion of the regenerating chamber so that the blowing air is uniformly distributed inside the regenerating chamber by the blowing air inserted into the blowing inlet portion by the hot air blowing portion and bent downward.

The blowing air is blown over the central portion of the bottom surface of the regenerating chamber so that the blowing air is uniformly distributed inside the regenerating chamber.

The blowing air is blown over the central portion of the bottom surface of the regenerating chamber so that the blowing air is evenly distributed inside the regenerating chamber.

The blowing air baffle is blown to the bottom surface of the regenerating chamber to distribute the blowing air evenly inside the regenerating chamber by providing the blowing baffle provided at the opposite side of the blowing inlet portion with the hot air blowing portion at a predetermined angle inclined downward to provide.

1 is a schematic view showing a conventional hot air furnace.
2 is a thermal distribution diagram showing uneven thermal distribution of a conventional hot air furnace heat storage chamber.
3 is an enlarged view showing a conventional hot-air furnace thermal storage chamber.
4 is a configuration diagram showing an apparatus for blowing airflow equalization in a hot air storage room according to a first embodiment of the present invention;
5 is a configuration view showing an apparatus for blowing airflow equalization in a hot air storage room according to a second embodiment of the present invention;
6 is a configuration diagram showing an apparatus for blowing airflow equalization in a hot air storage room according to a third embodiment of the present invention;
7 is a configuration diagram showing an apparatus for blowing airflow equalization in a hot air storage room according to a fourth embodiment of the present invention;
8 is an analytical view showing a result of a flow simulation simulation for a conventional hot air furnace heat storage chamber.
9 is an explanatory view showing a simulation result of a flow simulation for an air flow equalizing apparatus in a hot air storage room according to a second embodiment of the present invention;

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

Fig. 4 is a configuration diagram showing an apparatus for equalizing the airflow of a hot air storage room according to a first embodiment of the present invention, and Fig. 5 is a diagram showing an apparatus for equalizing an airflow in a hot air storage room according to a second embodiment of the present invention And FIG. 6 is a schematic view showing an apparatus for equalizing an air flow in a hot air storage room according to a third embodiment of the present invention, and FIG. 7 is a view showing an apparatus for equalizing an air flow in a hot air storage room according to a fourth embodiment of the present invention And FIG. 9 is a graph showing a simulation result of a flow simulation for an airflow equalizing apparatus in a hot air storage room according to a second embodiment of the present invention. FIG. Fig.

4, the apparatus for equalizing the temperature of the hot air storage room according to the first embodiment includes a blowing inlet 10 and a blower equal part 20, (112) of the hot air storage room.

The air blowing inlet portion 10 is a blowing air inflow passage formed at a lower portion of the hot air furnace heat generating chamber 110 and through which air is introduced and flows into the lower space 112 of the hot air furnace heat generating chamber 110, And is opened at one side of the lower portion of the wall of the chamber 110.

The air blowing equalizing section 20 is blowing equalizing means provided in the blowing inflow section 10 and blowing to the lower side of the regenerating chamber 110 to uniformly maintain the blowing air in the lower space 112 of the regenerating chamber 110, And a blowing insertion tube 21 inserted into the blowing inlet 10 so as to blow downward into the lower space 112 of the heat storage chamber 110 and having a tip end 21a bent downward.

The air blowing inlet tube 21 is provided at a central portion of the lower space 112 so that the air introduced through the air blowing inlet portion 10 is blown downward toward the bottom of the central portion of the lower space 112 of the heat storage chamber 110, And the tip end 21a is bent substantially vertically downward.

Accordingly, the blowing air is blown downward from the central portion of the lower space 112 of the regenerative chamber 110 to collide against the bottom of the lower space 112, and then is dispersed to the outer portion of the lower space 112 to be moved upward So that the blowing air is uniformly distributed inside the heat storage chamber 110.

As shown in Fig. 5, the apparatus for equalizing the air in the hot air furnace regenerating chamber according to the second embodiment comprises an air blowing inlet 10 and an air blowing equalizer 20. The blowing inflow section 10 of the second embodiment is the same as the blowing inflow section 10 of the first embodiment and a detailed description thereof will be omitted and only the blowing section 20 of the second embodiment having different configurations will be described.

The blower unit 20 of the second embodiment is provided with a blowing vane 22 having a plurality of guide plates arranged at a predetermined angle to the blowing inlet 10 so as to be inclined downward into the lower space 112 of the heat storage chamber 110 consist of.

The blowing vane 22 is installed such that the guide plate is inclined downward at a first inclination angle? With respect to the direction of blowing in and out of the blowing inlet 10 so that the blowing air is blown into the lower space 112 of the heat storage chamber 110 And the bottom surface is sprayed toward the central portion.

It is preferable that the first inclination angle alpha is in a range of 30 to 50 degrees downward with reference to the airflow inflow direction of the airflow inflow section 10. [ This is because when the first inclination angle a is out of the above range, the blowing air is not blown toward the central portion of the bottom surface of the lower space 112 of the heat storage chamber 110, and the turbulent flow of the blowing air is not smoothly formed This is because uneven thermal distribution is formed inside the heat storage chamber 110.

Accordingly, the blowing air is blown over the center of the bottom surface of the lower space 112, collides with the central portion of the bottom surface of the lower space 112, and then forms a turbulent flow which is dispersed to the outer portion of the lower space 112 and moves upward So that the blowing air is uniformly distributed inside the heat storage chamber 110.

As shown in Fig. 6, the apparatus for blowing air in the hot air furnace regulating chamber according to the third embodiment comprises an air blowing inlet portion 10 and an air blowing equalizing portion 20. The blowing inlet portion 10 of the third embodiment is the same as the blowing inlet portion 10 of the first embodiment and a detailed description thereof will be omitted and only the blower portion 20 of the third embodiment will be described.

The air blowing fan unit 20 of the third embodiment has an air blowing inlet pipe 23 whose tip is downwardly inclined at a predetermined angle to the blowing inlet 10 so as to slant downwardly into the lower space 112 of the heat storage chamber 110, Lt; / RTI >

The air blowing inlet pipe 23 is inclined downward at a second inclination angle? With respect to the air blowing direction of the air blowing inlet 10 so that the blowing air is blown into the bottom surface 112 of the regenerating chamber 110 And is sprayed toward the central portion.

It is preferable that the second inclination angle beta is in the range of 30 to 50 degrees downward with reference to the airflow inflow direction of the airflow inflow section 10. [ This is because when the second inclination angle beta is out of the above range, the blowing air is not sprayed toward the central portion of the bottom surface of the lower space 112 of the heat storage chamber 110, so that the turbulent flow of the blowing air is not smoothly formed This is because uneven thermal distribution is formed inside the heat storage chamber 110.

Accordingly, since the blowing air is blown over the center of the bottom surface of the lower space 112 and collides with the bottom surface of the lower space 112, the turbulent flow is dispersed to the outer space of the lower space 112, The blowing air is uniformly distributed inside the heat storage chamber 110.

As shown in Fig. 7, the apparatus for blowing air in the hot air furnace regulating chamber according to the fourth embodiment comprises an air blowing inlet 10 and an air blowing equalizer 20. The blowing inlet 10 of the fourth embodiment is the same as the blowing inlet 10 of the first embodiment and a detailed description thereof will be omitted and only the blower equal part 20 of the fourth embodiment will be described.

The air blowing induction plate 20 of the fourth embodiment is arranged such that the blowing induction plate is inclined downward at a predetermined angle to the opposed portion of the blowing inlet 10 to guide the blowing air introduced into the lower space 112 of the heat storage chamber 110 downward And an installed wind blowing baffle 24.

The blowing baffle 24 is installed such that the blowing induction plate is inclined rearward at a third inclination angle? With respect to a vertical surface opposed to the blowing and inflow direction of the blowing inlet 10, (Not shown).

It is preferable that the third inclination angle? Is in the range of 20 to 40 degrees downward with reference to the air blowing and inflow direction of the air blowing inlet portion 10. This is because if the third inclination angle γ is out of the above range, the blowing air is not blown toward the bottom surface of the lower space 112 of the heat storage chamber 110, so that turbulent flow of the blowing air is not smoothly formed, This is because the mounting area of the baffle 24 is increased, so that uneven heat distribution is formed in the heat storage chamber 110.

Accordingly, since the blowing air is blown to the bottom surface of the lower space 112 and impinges on the bottom surface of the lower space 112, the turbulent flow is formed which is dispersed to the inside and outside of the lower space 112 and moves upward , The blowing air is uniformly distributed inside the heat storage chamber (110).

In other words, according to the first to fourth embodiments of the present invention, various types of blower portions 20 are provided in the vicinity of the blowing inlet 10 to cause the blowing air to generate turbulence, The heat is uniformly distributed in the lower space 112 of the heat storage chamber 110 and the heat storage checker row 111 as the upper space thereof to uniformly transmit heat to the internal space of the heat storage chamber 110. As a result, .

Specifically, as shown in Fig. 8, the conventional hot-air furnace regenerating chamber 110 is maintained in a state in which the heat distribution of the heat distribution inside the furnace is uneven, but according to the hot-air equalizing unit 20 of the second embodiment of the present invention As shown in FIG. 9, since the heat dissipation of the heat distribution in the hot-air storage room 110 is maintained in a uniform state, the thermal efficiency of the entire hot-air path is increased.

As described above, according to the present invention, by providing various types of hot air uniform parts in the hot air inflow part formed in the lower part of the hot air space regulating room, turbulent flow is induced in the blowing air, and the blowing air is uniformly distributed So that the heat transfer is uniformly transmitted, thereby increasing the thermal efficiency of the entire hot air path.

In addition, since the blowing air is uniformly distributed by the hot air cracking part in the hot air storage room, the thermal efficiency of the hot air path is increased to reduce the operation cost, and the check quantity of the heat storage room and the amount of the refractory are reduced, .

Further, the blowing air is blown downward from the lower central portion of the regenerating chamber, so that the blowing air is uniformly distributed in the regenerating chamber by providing the blowing air insertion tube which is inserted into the blowing inlet portion and bent downwardly.

The blowing air is blown over the central portion of the bottom surface of the regenerating chamber so that the blowing air is evenly distributed inside the regenerating chamber by providing the blowing vane provided with the plurality of guide plates at a predetermined angle inclination in the blowing inlet portion with the hot air equalizing portion.

The blowing air is blown over the central portion of the bottom surface of the regenerating chamber to distribute the blowing air evenly in the regenerating chamber by providing the blowing inlet pipe provided with the blowing inlet portion provided with the tip end downwardly inclined at a predetermined angle to the blowing inlet portion with the hot air equalizing portion.

In addition, since the blowing baffle provided with the blowing induction plate at a predetermined angle inclined downward is provided at the opposed portion of the blowing inflow portion by the hot air equalizing portion, the blowing air is blown to the bottom face of the heat regulating chamber to distribute the blowing air evenly inside the heat regulating chamber Effect.

The present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. Therefore, the above embodiments are merely illustrative in all respects and should not be construed as limiting.

10: Hot air inflow part
20:

Claims (5)

delete An apparatus for equalizing an airflow in a hot air storage room provided in a lower space of a hot air storage room,
An air blowing inlet formed at a lower portion of the hot air furnace heat storage chamber and through which air is introduced; And
And an air blowing equalizing portion provided in the blowing inlet portion and blowing to the lower side of the regenerating chamber to uniformly maintain air blowing in a lower space of the regenerating chamber,
Wherein the air blowing equalizing portion includes an air blowing insertion tube inserted into the air blowing inlet portion so as to blow downward into the lower space of the heat storage room and whose tip is bent downward. An apparatus for equalizing an airflow in a hot air storage room provided in a lower space of a hot air storage room,
An air blowing inlet formed at a lower portion of the hot air furnace heat storage chamber and through which air is introduced; And
And an air blowing equalizing portion provided in the blowing inlet portion and blowing to the lower side of the regenerating chamber to uniformly maintain air blowing in a lower space of the regenerating chamber,
Wherein the air blowing equalizing unit includes an air blowing vane having a plurality of guide plates sloped at a predetermined angle on the blowing inlet so as to be inclined downwardly in the lower space of the regenerating chamber. An apparatus for equalizing an airflow in a hot air storage room provided in a lower space of a hot air storage room,
An air blowing inlet formed at a lower portion of the hot air furnace heat storage chamber and through which air is introduced; And
And an air blowing equalizing portion provided in the blowing inlet portion and blowing to the lower side of the regenerating chamber to uniformly maintain air blowing in a lower space of the regenerating chamber,
Wherein the airflow equalizing section includes a blowing inlet pipe having a tip end inclined downward at a predetermined angle to the blowing inlet so as to slant downwardly into a lower space of the regenerating chamber. An apparatus for equalizing an airflow in a hot air storage room provided in a lower space of a hot air storage room,
An air blowing inlet formed at a lower portion of the hot air furnace heat storage chamber and through which air is introduced; And
And an air blowing equalizing portion provided in the blowing inlet portion and blowing to the lower side of the regenerating chamber to uniformly maintain air blowing in a lower space of the regenerating chamber,
Wherein the blowing-out portion includes a blowing baffle provided at an opposite portion of the blowing inlet portion so as to downwardly guide the blowing air introduced into the lower space of the regenerating chamber, the blowing induction plate being downwardly inclined at a predetermined angle. Blowing equalization device.

Images