JP2012241204A - Ceramic burner for hot blast stove - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a ceramic burner for a hot blast stove, which can raise combustion efficiency.SOLUTION: The ceramic burner 9 for a hot blast stove includes a cylindrical body 91, a combustion air passage 95 divided with a plurality of partition walls 92 inside of the body 91, and a fuel gas passage 96. The ceramic burner 9 is characterized in that the combustion air passage 95 and the fuel gas passage 96 are formed alternately and a swirl means 100 for generating swirling airflow which swirls around the vertical axis of the body is arranged above both the combustion air passage 95 and the fuel gas passage 96.

Description

  The present invention relates to a ceramic burner for a hot stove.

Conventionally, a hot stove is used to supply hot air to a blast furnace. In an internal combustion type hot stove, a combustion chamber for burning fuel gas and a heat storage chamber filled with a heat storage brick are formed inside the furnace body. The combustion chamber is formed in a substantially elliptical region surrounded by the inner side of the arc and the wall of the furnace body in a cross-sectional view when the inside of the furnace body of the cylindrical hot-air furnace is partitioned by an arc-shaped partition. Yes.
A ceramic burner is provided below the combustion chamber. This ceramic burner is divided into a plurality of partitions by partition walls, and fuel gas passages through which fuel gas flows and combustion air passages through which combustion air flows are alternately formed. The fuel gas supplied from the lower part of the ceramic burner rises through the fuel gas passage, and the combustion air supplied from the lower part of the ceramic burner rises through the combustion air passage. The rising fuel gas and combustion air are mixed by lattice bricks (lattice portions) at the top of the ceramic burner and burned in the combustion chamber. The combustion gas is guided to the heat storage chamber and stores heat in the heat storage bricks in the heat storage chamber. After storing heat in the heat storage chamber, combustion is stopped, air is sent into the heat storage chamber to form high temperature air, and this high temperature air is supplied to the blast furnace.

In the conventional ceramic burner, the partition walls are arranged along the substantially elliptical long axis direction, and the fuel gas passages and the combustion air passages are alternately formed along the long axis direction in a cross-sectional view. . When the fuel gas supplied from the lower part of the ceramic burner and the combustion air rise in both passages, the gas passage and the air passage are respectively arranged so that no concentration distribution of gas or air occurs in the major axis direction. This is a substantially trapezoidal space that extends from the inlet to the combustion chamber. This substantially trapezoidal space is formed by being surrounded by a vertical wall extending vertically from the fuel gas and combustion air inlet side, an inclined wall located on the opposite side of the vertical wall, and a partition wall. Is done. In addition, the inclination direction of the inclined wall is different between the gas passage and the air passage. That is, the inclined wall of the gas passage is inclined from one end side to the other end side of the substantially elliptical long axis, whereas the inclined wall of the air passage is the other end side of the substantially elliptical long axis. It inclines toward one end side.
In the ceramic burner having such a structure, when the fuel gas and the combustion air are circulated, there is a problem that the variation in the mixing ratio between the combustion air and the fuel gas in the cross section is large and the combustion efficiency is low.

  For such a problem, for example, in Patent Document 1, by devising the arrangement and shape of the key bricks installed in the ceramic burner, variation in the mixing ratio is suppressed and combustion efficiency is improved. .

Japanese Patent Publication No.62-10323

  However, as described in Patent Document 1, even if the arrangement and shape of the key bricks are devised, the variation in the mixing ratio is not sufficiently suppressed, and further improvement in the combustion efficiency of the hot stove is desired.

  The objective of this invention is providing the ceramic burner for hot-air stoves which can improve combustion efficiency.

  The inventors of the present invention have made extensive studies to solve the above-described problems. As a result, in the combustion air passage and the fuel gas passage, the vertical wall side is more vertical than the combustion air and fuel gas rising along the inclined wall. We found that there were more combustion air and fuel gas rising in the direction. And since the arrangement of the inclined wall and the vertical wall of the combustion air passage and the fuel gas passage is alternately different as described above, the lattice portion has a large amount of fuel gas at one end side of the substantially elliptical long axis, It was found that the mixture was mixed with a small amount of combustion air, and the other end of the same long axis was mixed with a large amount of combustion air and a small amount of fuel gas, resulting in a large variation in the mixing ratio in the cross section. . The present invention has been completed based on such findings.

The ceramic burner for a hot stove of the present invention is
A hot air furnace ceramic burner having a cylindrical main body, a combustion air passage partitioned by a plurality of partition walls inside the main body, and a fuel gas passage,
The combustion air passage and the fuel gas passage are alternately formed,
A swirling means for generating a swirling airflow swirling around a vertical axis of the main body is provided above the combustion air passage and the fuel gas passage.

  In the present invention, swirling means for generating a swirling airflow swirling around the vertical axis of the main body is provided above the combustion air passage and the fuel gas passage. Therefore, the combustion air and fuel gas after passing through each passage are agitated by the swirling airflow generated by the swirling means. Therefore, the above-described variation in the mixing ratio between the combustion air and the fuel gas can be suppressed. As a result, the combustion efficiency in the hot stove can be improved.

In the ceramic burner for a hot stove of the present invention,
The swirling means includes an air jet port disposed in the swirling direction of the swirling airflow above the combustion air passage and the fuel gas passage,
It is preferable that the air jet outlet ejects the supplied air branched from a combustion air introduction path for supplying air to the combustion air passage.

  In such this invention, the air jet outlet is arrange | positioned toward the turning direction of a turning airflow above a combustion air channel | path and a fuel gas channel | path. Therefore, a swirl airflow can be easily generated. In addition, since the air jetted from the air outlet uses a part of the air supplied to the combustion air passage, a separate facility for generating a swirling airflow becomes unnecessary, and the equipment cost is reduced. The rise can be prevented.

In the ceramic burner for a hot stove of the present invention,
At the upper end of the combustion air passage and the fuel gas passage, a lattice portion constructed in a lattice shape with bricks is provided,
It is preferable that a guide blade projecting toward the swirling direction of the swirling airflow is formed on the lattice portion.

In the present invention as described above, the guide blade is formed in the lattice portion so as to project toward the swirling direction of the swirling airflow. Therefore, the combustion air that has passed through the combustion air passage and the fuel gas passage and reaches the lattice portion and the fuel gas are mixed, and the flow in the swirl direction is easily generated by the guide blade. Normally, the airflow after passing through the lattice portion has a main component in the vertical direction.In the present invention, however, a swirling airflow is generated above the lattice portion as a result of the flow in the swirling direction being easily generated. Variations in the mixing ratio with the fuel gas can be suppressed.
In the present invention as described above, the above-described air outlet may be used in combination.

In the ceramic burner for a hot stove of the present invention,
It is preferable that the combustion air passage is formed on the outermost side among the plurality of combustion air passages and the fuel gas passages alternately formed in the main body.

  In the present invention, if the outer passage is a combustion air passage, a combustion air ascending air flow is formed on both sides of the fuel gas ascending air flow, so that the fuel gas rises without being mixed with the combustion air. Can be prevented.

The longitudinal cross-sectional view which shows the hot stove of 1st Embodiment of this invention. The cross-sectional view of the straight body part of the hot stove in the first embodiment. The expanded longitudinal cross-sectional view of the ceramic burner in the said 1st Embodiment. The longitudinal cross-sectional view of the direction different from FIG. 3 of the ceramic burner in the said 1st Embodiment. The expansion perspective view of the ceramic burner in the said 1st Embodiment. The top view of the ceramic burner of 2nd Embodiment of this invention. The expanded longitudinal cross-sectional view of the ceramic burner in the said 2nd Embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
FIG. 1 shows a hot stove 1 equipped with a ceramic burner for a hot stove of the present invention.
In FIG. 1, a hot stove 1 has a furnace body 3 installed on a foundation 2. The furnace body 3 has a cylindrical straight body portion 6, a conical portion 5 formed on the upper portion of the straight body portion 6 with a slightly larger diameter, and a hemispherical dome portion 4 installed on the upper surface of the conical portion 5. . A combustion chamber 7 and a heat storage chamber 8 are formed inside the straight body 6 and are separated from each other by a brick wall. A ceramic burner 9 for sending high-temperature combustion gas into the combustion chamber 7 is provided below the combustion chamber 7. A combustion air introduction port 10 and a fuel gas introduction port 11 are provided on the combustion chamber 7 side of the furnace body 3.

  The combustion chamber 7 is divided into a furnace body 3 by a partition 71 having a circular cross section (see FIG. 2), and is formed in a substantially elliptical region surrounded by the inside of the arc and the inner wall of the furnace body 3. . The combustion chamber 7 has a gas passage 72 in which the substantially elliptical region continues from above the ceramic burner 9 to the conical portion 5 and extends vertically (see FIG. 1).

The heat storage chamber 8 is formed in a region surrounded by the outer side of the arc of the partition 71 and the inner wall of the furnace body 3. This region continues from the bottom of the furnace body 3 to the conical part 5. As shown in FIG. 1, heat storage bricks 81 are arranged in the heat storage chamber 8, thereby forming a heat storage body 82 that fills the entire heat storage chamber 8. The heat storage body 82 is supported by a support body 83 installed at the bottom of the heat storage chamber 8.
In the heat storage body 82, each of the heat storage bricks 81 has a vent hole penetrating vertically, and the vent holes are arranged so as to be continuous with each other (not shown), and the support body is supported from the upper surface side of the heat storage body 82. Up to 83, ventilation is possible as a whole.

As shown in FIG. 1 or 4, the furnace body 3 is formed with a combustion air inlet 10, a fuel gas inlet 11, an outside air communication port 12, and a hot air outlet 13.
The combustion air introduction port 10 and the fuel gas introduction port 11 are formed in the lower part of the straight body portion 6 on the combustion chamber 7 side. As shown in FIG. 4, a combustion air introduction pipe 14 as a combustion air introduction path is connected to the combustion air introduction port 10. A fuel gas introduction pipe 15 as a fuel gas introduction path is connected to the fuel gas introduction port 11.
As shown in FIG. 1, the outside air communication port 12 is formed in a lower portion of the straight body portion 6 on the heat storage chamber 8 side, and communicates with a hollow portion below the support 83.
As shown in FIG. 1, the hot air outlet 13 is formed at an intermediate height on the combustion chamber 7 side of the straight body portion 6 and communicates with the gas passage 72 of the combustion chamber 7.

The ceramic burner 9 raises the combustion air introduced into the furnace body 3 from the combustion air inlet 10 and the fuel gas introduced into the furnace body 3 from the fuel gas inlet 11. Mix and burn.
1-4, the ceramic burner 9 includes a cylindrical main body 91, a partition wall 92, a vertical wall 93, an inclined wall 94, a combustion air passage 95, a fuel gas passage 96, and a lattice portion 97. And swivel means 100.
The cylindrical main body 91 is assembled from bricks, and has a substantially elliptical cross section continuous in the vertical direction in a cross-sectional view as in the combustion chamber 7. In the lower part of the main body 91, an air introduction chamber 98A communicating with the combustion air introduction port 10 and a fuel gas introduction chamber 98B communicating with the fuel gas introduction port 11 are formed. The air introduction chamber 98A and the fuel gas introduction chamber 98B are partitioned by a partition wall 98C so that the air and fuel gas introduced into each of the air introduction chamber 98A and the fuel gas introduction chamber 98B are not mixed.
The partition wall 92, the vertical wall 93, and the inclined wall 94 partition the inside of the main body 91 and are assembled from bricks.
A plurality of partition walls 92 are provided above the air introduction chamber 98A and the fuel gas introduction chamber 98B. A plurality of the partition walls 92 are arranged along the direction of the major axis 91A having a substantially elliptical cross section of the main body 91 shown in FIG. A predetermined interval is provided between the partition walls 92, and a spacer member (not shown) made of a refractory called a key brick is incorporated between the partition walls 92 in order to maintain this interval. A vertical wall 93 is continuously formed at one side end of the partition wall 92, and an inclined wall 94 is continuously formed at the other side end.

  The combustion air passage 95 is a space for allowing air introduced into the air introduction chamber 98 </ b> A to pass upward of the ceramic burner 9. The fuel gas passage 96 is a space for allowing the fuel gas introduced into the fuel gas introduction chamber 98 </ b> B to pass above the ceramic burner 9. These spaces are formed by partitioning the inside of the main body 91 by a partition wall 92, a vertical wall 93, and an inclined wall 94. The combustion air passages 95 and the fuel gas passages 96 are alternately arranged along the direction of the long axis 91A. Therefore, the combustion air introduced into the air introduction chamber 98 </ b> A and the fuel gas introduced into the fuel gas introduction chamber 98 </ b> B alternately pass toward the lattice portion 97 through the partition wall 92.

As shown in FIG. 4, the combustion air passage 95 and the fuel gas passage 96 are substantially trapezoidal spaces in a longitudinal sectional view, and the upper and lower sides are open. In FIG. 4, the combustion air passage 95 is indicated by a solid line, and the fuel gas passage 96 is indicated by a broken line.
The inclined wall 94A of the combustion air passage 95 is inclined toward the side opposite to the vertical wall 93A continuous in the vertical direction from the air introduction chamber 98A. On the other hand, the inclined wall 94B of the fuel gas passage 96 is inclined toward the opposite side of the vertical wall 93B continuous in the vertical direction from the fuel gas introduction chamber 98B. That is, the inclination direction of the inclined wall 94A of the combustion air passage 95 and the inclination direction of the inclined wall 94B of the combustion air passage 95 intersect as shown in FIG. Therefore, the combustion air introduced into the combustion air passage 95 and the fuel gas introduced into the fuel gas passage 96 rise not only in the vertical direction but also while spreading in the directions of the inclined walls 94A and 94B. As a result, the fuel gas and the combustion air pass through the longitudinal direction (corresponding to the long axis direction) of the opening at the upper end of the combustion air passage 95 and the fuel gas passage 96.

  As described above, the combustion air passages 95 and the fuel gas passages 96 are alternately arranged, but the combustion air passages 95 are preferably formed on the outermost side. If the flow path formed on the outermost side is the combustion air passage 95, the fuel gas can be prevented from rising without being mixed with the combustion air.

The lattice unit 97 mixes the fuel gas and the combustion air that have passed through the combustion air passage 95 and the fuel gas passage 96, and burns the fuel gas.
FIG. 5 is an enlarged perspective view showing a part of the lattice portion 97.
The lattice portion 97 is assembled from bricks, and as shown in FIGS. 2 to 5, a plurality of support portions 97A and a plurality of flow dividing portions 97B are combined in a lattice shape.
The support portions 97A are provided in a plurality of rows on the upper end side of the partition walls 92 in a direction crossing the arrangement direction of the partition walls 92, and support the flow dividing portions 97B. The support portions 97A are provided at substantially equal intervals along the direction of the short axis 91B having the substantially elliptical cross section described above.
As shown in FIG. 3, the diversion unit 97 </ b> B diverts the fuel gas and the combustion air that have passed through the combustion air passage 95 and the fuel gas passage 96 into two adjacent passages. One split fuel gas and one split combustion air join together while rising and are mixed. The diversion portions 97B are provided at substantially equal intervals along the direction intersecting the installation direction of the support portion 97A and the direction of the major axis 91A having the substantially elliptical cross section described above. As shown in FIGS. 3 and 5, each of the diversion portions 97 </ b> B is located between the adjacent partition walls 92.

The swirling means 100 generates a swirling airflow that swirls around the vertical axis of the main body 91.
As shown in FIG. 1, the swirling means 100 includes a branch pipe 110 that branches from the combustion air introduction pipe 14 to the upper part of the lattice portion 97, an air jet outlet 120 provided at the end of the branch pipe 110, An orifice 130 connected between the branch point from the introduction pipe 14 and the air outlet 120, an air flow rate adjustment valve (air flow adjustment valve) 140, and an air valve 150 are provided.
The branch pipe 110 is connected in the middle of the combustion air introduction pipe 14, and guides guide air for branching a part of the combustion air to generate a swirling airflow to the air jet outlet 120. As shown in FIG. 1, the branch pipe 110 is connected to the front side of the combustion air flow rate adjustment valve 14 </ b> A of the combustion air introduction pipe 14.
Further, in this embodiment, as shown in FIG. 2, two systems of branch pipes 110 are provided. One is disposed on one end side of the long shaft 91A, and the other is disposed on the other end side of the long shaft 91A.
The air outlet 120 ejects the induction air supplied from the branch pipe 110. In the present embodiment, the air outlet 120 is an opening formed on the inner wall of the furnace body 3. The air jets 120 are respectively attached to the aforementioned two systems of branch pipes 110 and are located above the lattice portion 97. The direction of the air outlet 120 of the air outlet 120 is in the direction of the swirling airflow. Specifically, the direction of the spout is formed in a direction along the tangential direction of the main body 91 having a substantially elliptical cross section. In the present embodiment, as shown in FIG. 2, the guide air is ejected from the air outlets 120 provided on one end side and the other end side of the long shaft 91 </ b> A, thereby generating a swirling airflow in the counterclockwise direction.
The flow rate of the induced air branched from the combustion air introduction pipe 14 is reduced by the orifice 130, the flow rate is adjusted by the air flow rate adjustment valve 140, and the generation of the swirling airflow is controlled by the air valve 150.

According to the first embodiment as described above, the following effects are obtained.
The ceramic burner 9 includes the above-described swirling means 100, and the induced air ejected from the air ejection port 120 generates a swirling airflow in the cross-sectional direction above the lattice portion 97, and the combustion air that has passed through the combustion air passage 95, The fuel gas that has passed through the fuel gas passage 96 is stirred. Therefore, the dispersion | variation in the mixing ratio of combustion air and fuel gas can be suppressed.
In particular, in the case of a hot stove in which combustion air passages 95 and fuel gas passages 96 are alternately formed along the direction of the long axis 91A as in this embodiment, one end side of the long axis 91A immediately after passing through the lattice portion 97 is The fuel gas concentration is high and the air concentration is low, and the other end side of the long axis 91A tends to have a low fuel gas concentration and a high air concentration. Even in such a case, the turning means 100 can suppress the above-described variation in the mixing ratio. As a result, the combustion efficiency in the hot stove 1 can be improved.

  As described above, the air jets 120 are arranged on one end side and the other end side of the long shaft 91A, and guide air is jetted from the respective air jets 120 toward the swirling direction of the swirling airflow. An air flow can be generated more easily.

  Since the guide air ejected from the swirl means 100 uses a part of the air supplied to the combustion air passage 95, a separate facility for generating the swirl airflow becomes unnecessary, and the equipment cost is reduced. The rise can be prevented.

  Since the branch pipe 110 is disposed inside the main body 91, the induction air is preheated while passing through the branch pipe 110. Since the induction air ejected from the air ejection port 120 is preheated, the spalling of the inner wall brick of the furnace body 3 can be prevented.

[Second Embodiment]
The ceramic burner 19 in the second embodiment is different from the ceramic burner 9 in the first embodiment in the shape of the lattice portion. The turning means in the second embodiment corresponds to a lattice portion having a characteristic shape. In the following description, the same parts as those already described are denoted by the same reference numerals, and the description thereof is omitted or simplified.

FIG. 6 is a top view of the ceramic burner 19 and shows the shape of the lattice portion 197 of the ceramic burner 19. The lattice part 197 is assembled from bricks like the lattice part 97 of the first embodiment, and a plurality of support parts 197A and a plurality of flow dividing parts 197B are combined in a lattice shape.
As shown in FIG. 6, the support portion 197A has a guide blade 197C projecting in the width direction of the support portion 197A, and the flow dividing portion 197B has a guide blade 197D projecting in the width direction of the flow split portion 197B. The guide blade 197C and the guide blade 197D guide the direction of the rising air flow of combustion air and fuel gas so that a swirling air current is easily generated. The protruding width dimension of the guide blade 197C and the guide blade 197D increases from the center of the above-mentioned substantially elliptical cross section toward the outside, and is inclined as shown in FIG.

FIG. 7 is an enlarged vertical cross-sectional view of the ceramic burner 19 as viewed in the direction of the arrow VII-VII in FIG.
As shown in FIG. 7, the guide blade 197D is inclined in the above-described protruding direction from the lower part to the upper part of the guide blade 197D. The guide blade 197C is also inclined similarly to the guide blade 197D.
In the present embodiment, as shown in FIG. 6, the direction in which the guide blade 197C and the guide blade 197D protrude is divided into four regions D1, which can be divided into a substantially elliptical cross section by a major axis 91A and a minor axis 91B, The direction is different in each of the region D2, the region D3, and the region D4. In order to generate a swirl airflow in the counterclockwise direction, the guide blade 197C and the guide blade 197D project toward the swirl direction of the swirl airflow. Specifically, as shown in FIG. 6, in the region D1, the guide blade 197C is upward, in the region D2, the guide blade 197D is leftward, in the region D3, the guide blade 197C is downward, and in the region D4 Then, the guide blades 197D protrude in the right direction.
FIG. 7 shows the state of the flow dividing portion 197B in the region D1 and the region D2. In the region D2, the combustion air and the fuel gas that have risen in the combustion air passage 95 and the fuel gas passage 96 are likely to flow along the inclination direction of the guide blade 197D (upwardly in the left direction in FIG. 7). Become. In the region D1, since the flow dividing portion 197B does not have the guide blade 197D, the flow rising in the vertical direction becomes the main flow.

According to the second embodiment as described above, the following effects are obtained.
In the lattice portion 197 of the ceramic burner 19, the support portion 197A has a guide blade 197C, and the flow dividing portion 197B has a guide blade 197D. Therefore, in the lattice portion 197, the combustion air and the fuel gas that have passed through the combustion air passage 95 and the fuel gas passage 96 to reach the lattice portion 197 are mixed, and the direction in which the induction blade 197C and the induction blade 197D protrude. , That is, an airflow in a direction inclined with respect to the vertical direction is likely to be generated. As a result, a swirling airflow swirling around the vertical axis of the main body 91 is generated above the lattice portion 197, and variation in the mixing ratio between the combustion air and the fuel gas can be suppressed. Therefore, the combustion efficiency in a hot stove can be improved.

  Since the extending directions of the guide blade 197C and the guide blade 197D are sequentially changed for each of the regions D1 to D4 so that a counterclockwise swirl airflow is likely to be generated, the swirl airflow can be easily generated.

[Modification of Embodiment]
Note that the present invention is not limited to the above-described embodiments, and specific configuration of each part can be appropriately modified during implementation.

In the first embodiment described above, the gas supplied from the nozzle is air, but a gas other than air can be used as long as the combustibility in the hot stove is not impaired.
Further, the air jets 120 are not limited to two places as in the first embodiment described above, but may be one place, or a plurality of places may be formed along the inner circumference having a substantially elliptical cross section.
In addition, although it demonstrated in the aspect which arrange | positions the branch pipe 110 inside the main body 91 of the ceramic burner 9, it is not restricted to this. For example, a mode in which the branch pipe 110 is not disposed inside the main body 91 may be employed. Specifically, a hole for communicating the inside and outside of the furnace body 3 is formed in the brick wall of the main body 91, the branch pipe 110 is connected to the outside of the furnace body 3, and the air outlet 120 is provided inside the furnace body 3. Form.

In the second embodiment described above, the guide blade 197C and the guide blade 197D protrude while being inclined as shown in FIG. 7, but are not limited to such an extended shape. Any shape that projects in the direction of the swirling airflow may be used. For example, the swirling airflow may project in a rectangular shape or a curved shape.
Further, the projecting direction of the guide blade 197C and the guide blade 197D is not limited to the direction shown in FIG. 6, and may be opposite to the projecting direction in each of the regions D1 to D4 shown in FIG. Moreover, the area | region which divides cross-sectional substantially elliptical shape is not limited to four as mentioned above. Further, in each region, one of the support portion 197A and the flow dividing portion 197B is projected, but in the same region, the guide blade 197C is formed on the support portion 197A, and the guide blade 197D is formed on the flow dividing portion 197B. May be.
Further, as shown in FIG. 6, the support portion 197A and the flow dividing portion 197B of the lattice portion 197 may be inclined without being formed in a straight line. For example, the support portion 197A may be inclined in the protruding direction of the guide blade 197C and the flow dividing portion 197B may be inclined in the protruding direction of the guide blade 197D in a cross-sectional view as shown in FIG.

  Furthermore, as described in the first embodiment, the air ejection port 120 is provided to eject the guide air, and the guide blades 197C and 197D can be formed as described in the second embodiment. By combining in this way, it becomes easy to generate a swirling airflow, variation in the mixing ratio between the combustion air and the combustion gas is further suppressed, and the combustion efficiency of the hot stove can be further improved.

  EXAMPLES Next, although an Example is given and this invention is demonstrated further more concretely, this invention is not limited to these Examples.

Example 1
As for the hot air furnace having a ceramic burner in which combustion air passages and fuel gas passages are alternately arranged along the major axis direction as described in the first embodiment, induction air is introduced to generate a swirling airflow. Combustion analysis was performed when it was generated. As the induction air, the total amount of combustion air was constant, and 20% of the air was used. Table 1 shows the conditions and results of the combustion analysis. The specification conditions of the hot stove facility were as follows: ^three single blasts, blast volume: 5100 Nm ³ / min, blast temperature: 1200 ° C. In Table 1, the fuel gas composition represents a mixed gas of blast furnace gas (BFG) and coke oven gas (COG). The unburned CO concentration ratio is the ratio of the unburned CO concentration of Example 1 to the unburned CO concentration of Comparative Example 1, and the unburned CO concentration of Comparative Example 1 is represented as 1.

(Comparative Example 1)
In the first comparative example, the induction air is not introduced as in the first example, and the combustion air passages and the fuel gas passages described in the first embodiment are alternately arranged along the long axis direction. Combustion analysis was performed in a hot stove equipped with a ceramic burner. Table 1 shows the conditions and results of the combustion analysis.

  As shown in Table 1, the unburned CO concentration ratio of Example 1 was 0.3, which was 70% lower than that of Comparative Example 1. In other words, as in the first embodiment, a swirling airflow is generated above the lattice portion, and the combustion air and the fuel gas are agitated, so that variation in the mixing ratio between the combustion air and the combustion gas is suppressed. It was found that the combustion efficiency was improved.

  The present invention can be used for a ceramic burner of a hot stove.

DESCRIPTION OF SYMBOLS 1 ... Hot stove 9, 19 ... Ceramic burner 91 ... Main body 91A ... Long axis 91B ... Short axis 92 ... Partition 95 ... Combustion air passage 96 ... Fuel gas passage 97, 197 ... Grid part 100 ... Swirling means 120 ... Air jet nozzle

Claims (4)

A hot air furnace ceramic burner having a cylindrical main body, a combustion air passage partitioned by a plurality of partition walls inside the main body, and a fuel gas passage,
The combustion air passage and the fuel gas passage are alternately formed,
A ceramic burner for a hot stove characterized in that swirling means for generating a swirling airflow swirling around a vertical axis of the main body is provided above the combustion air passage and the fuel gas passage. In the ceramic burner for a hot stove according to claim 1,
The swirling means includes an air jet port disposed in the swirling direction of the swirling airflow above the combustion air passage and the fuel gas passage,
The hot air furnace ceramic burner according to claim 1, wherein the air jet outlet jets air supplied by being branched from a combustion air introduction passage for supplying air to the combustion air passage. In the ceramic burner for a hot stove according to claim 1 or 2,
At the upper end of the combustion air passage and the fuel gas passage, a lattice portion constructed in a lattice shape with bricks is provided,
The lattice part is formed with induction blades extending toward the swirling direction of the swirling airflow. In the hot-burn furnace ceramic burner according to any one of claims 1 to 3,
A ceramic burner for a hot stove, wherein the combustion air passage is formed on the outermost side among the plurality of combustion air passages and the fuel gas passages alternately formed in the main body.