JP2007003147A - Acting burner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an acting burner capable of stably forming effect flame in a stationary state, and capable of further improving a staging effect. <P>SOLUTION: The acting burner 1 has an air draft pipe 2 and an inner fuel nozzle 3. The inner fuel nozzle 3 is comprised by plurally forming top face jet holes 311 for jetting out fuel gas F on a top face part 31, and forming a side face jet hole 321 for jetting out the fuel gas F on a side face part 32, and a baffle plate 34 surrounding a lower side and a side of a formed position of the side face jet hole 32 is provided on an outer circumference of the side face part 32. In the effect burner 1, the fuel gas F jetted out from the side face jet hole 321 is burned to form flame H3 for flame holding, and the fuel gas F jetted out from the top face jet holes 311 is burned to form the effect flame H1 in the stationary state from a top end opening 202 in the air draft pipe 2. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an effect burner configured to burn a fuel gas to form an effect flame.

  In a concert hall, a theme park, etc., various production burners are used to form a production flame. For example, in Patent Document 1, in a decorative gas burner, gas fuel having an oxygen concentration of 1% or less is pyrolyzed to generate floating carbon particles and hydrogen. The floating carbon particles and hydrogen are ejected from the decorative gas burner and burned with the surrounding air to form a flame having high brightness and high decorativeness like a candle. Further, the brightness of the flame is adjusted by changing the heating temperature of the gas fuel.

  However, the decorative gas burner of Patent Document 1 is not sufficient to further improve the effect of the flame. That is, in order to form a flame that is almost stationary, further ingenuity is required.

Japanese Patent No. 2708421

  The present invention has been made in view of such conventional problems, and intends to provide a production burner that can stably form a stationary production flame and can further improve the production effect. Is.

The present invention includes an air draft pipe for passing air from the lower end opening to the upper end opening;
An inner fuel nozzle that is disposed inside the air draft pipe and ejects fuel gas;
The inner fuel nozzle has a plurality of upper surface ejection holes for ejecting the fuel gas formed on the upper surface portion, and a side ejection hole for ejecting the fuel gas formed on the side surface portion. And a baffle plate surrounding the lower side and the side of the formation side of the side surface ejection hole on the outer periphery of the side surface part,
Combusting the fuel gas ejected from the side ejection holes to form a flame-holding flame, and combusting the fuel gas ejected from the upper surface ejection holes to form the upper end opening of the air draft pipe An effect burner is characterized in that it is configured so as to form a still-effect effect flame facing upward.

The production burner of the present invention has the air draft pipe and the inner fuel nozzle.
Then, when the production flame in the stationary state is formed by the production burner, the fuel gas is ejected from the upper surface ejection hole and the side surface ejection hole in the inner fuel nozzle. At this time, the air in the air draft pipe rises with the upward flow of the fuel gas, and the air flows into the air draft pipe from its lower end opening.

  In the air draft tube, the fuel gas burns in a state surrounded by air. Thus, the flame caused by the combustion of the fuel gas can form an almost stationary production flame from the inner fuel nozzle to above the upper end opening of the air draft pipe. The production effect by the production burner can be further improved.

  Further, when the fuel gas is ejected from the upper surface ejection hole in the inner fuel nozzle, the fuel gas is also ejected from the side surface ejection hole in the inner fuel nozzle. At this time, the fuel gas ejected from the side ejection holes is mixed with the air rising in the air draft pipe and burned to form a flame-holding flame. The baffle plate can prevent the air rising in the air draft pipe from directly colliding with the flame holding flame. Thereby, the flame for flame holding can be formed stably.

  Further, by forming a flame holding flame in the air draft tube, the fuel gas is prevented from performing lift combustion when the production flame is formed, and the production flame is prevented from passing through the upper end opening of the air draft tube. It can prevent forming from the position away from the predetermined distance. Thereby, the combustion in the production burner can be stabilized, and a stationary production flame can be stably formed.

  Therefore, according to the production burner of the present invention, a stationary production flame can be stably formed, and the production effect can be further improved.

A preferred embodiment of the present invention described above will be described.
In the present invention, the baffle plate includes, on the outer periphery of the side surface portion, a lower plate disposed below the position where the side surface ejection holes are formed, and a side plate disposed beside the position where the side surface ejection holes are formed. It preferably has a cross-sectional L shape.
In this case, it is easy to form the baffle plate, and the production flame can be stably formed by the production burner having a simple structure.

Further, it is preferable that the side surface ejection hole and the baffle plate are formed in a pair at positions facing each other.
In this case, in the inner fuel nozzle, flame holding flames can be formed at positions facing each other, and the production flame can be formed more stably.

  Further, an outer fuel nozzle for ejecting fuel gas is disposed outside the air draft pipe, and the outer fuel nozzle has an outer ejection hole for ejecting the fuel gas on the upper surface portion thereof. The production burner burns the fuel gas ejected from the upper surface ejection hole and combusts the fuel gas ejected from the outer ejection hole in the air draft pipe. It is preferable that a lively effect flame is formed above the upper end opening (claim 4).

In the production burner, when forming a lively production flame, the fuel gas is ejected from the inner fuel nozzle and the fuel gas is ejected from the outer fuel nozzle. At this time, the air in the air draft pipe rises with the upward flow of the fuel gas, and the air flows into the air draft pipe from its lower end opening.
In the air draft pipe, the fuel gas burns in a state surrounded by air, and the fuel gas ejected from the outer fuel nozzle burns outside the air draft pipe.

  At this time, an outer flame formed by the combustion of the fuel gas ejected from the outer fuel nozzle is formed around the inner flame caused by the combustion of the fuel gas ejected from the inner fuel nozzle. Further, the outer flame is formed so as to move upward while being prevented from being integrated with the inner flame by the air flowing out from the upper end opening. In addition, the entire flame by the inner flame and the outer flame is formed by a portion having a small cross-sectional outline and a portion having a large cross-sectional outline, and the portion having a large cross-sectional outline is repeatedly moved upward.

Thus, the entire flame can form a production flame in a state of dynamism toward the upper end opening of the air draft tube.
Also, when forming the dynamic flame for production, the flame holding flame can be formed in a state surrounded by the baffle plate by the fuel gas ejected from the side ejection holes. Therefore, it is possible to stably form a lively effect flame.

In the following, embodiments of the production burner of the present invention will be described with reference to the drawings.
As shown in FIGS. 1 to 9, the production burner 1 of this example is produced by using the visual effect of the flame by forming a stationary production flame H1 in a concert hall or a theme park. Is to do.

  As shown in FIGS. 1 to 3, the production burner 1 of the present example includes an air draft pipe 2 for allowing air A to pass from the lower end opening 201 to the upper end opening 202, and an inner side of the air draft pipe 2. An inner fuel nozzle 3 is provided for ejecting the fuel gas F, and an outer fuel nozzle 4 is provided outside the air draft pipe 2 for ejecting the fuel gas F.

The inner fuel nozzle 3 is formed with a plurality of upper surface ejection holes 311 for ejecting the fuel gas F on the upper surface portion 31, and side surface ejection holes 321 for ejecting the fuel gas F on the side surface portion 32. Formed. In addition, the inner fuel nozzle 3 includes a baffle plate 34 that surrounds the lower side and the side of the position where the side injection holes 321 are formed on the outer periphery of the side part 32.
The outer fuel nozzle 4 has a plurality of outer ejection holes 411 for ejecting the fuel gas F formed on the upper surface portion 41 thereof.

  Then, as shown in FIGS. 1 and 7, the production burner 1 burns the fuel gas F ejected from the side ejection holes 321 to form a flame holding flame H3 and ejects it from the upper surface ejection holes 311. The fuel gas F is burned to form a stationary effect flame H1 above the upper end opening 202 of the air draft pipe 2. Further, as shown in FIGS. 1 and 8, the effect burner 1 burns the fuel gas F ejected from the upper surface ejection hole 311, and combusts the fuel gas F ejected from the outer ejection hole 411 to generate air. A lively effect flame H2 is formed above the upper end opening 202 of the draft tube 2. Hereinafter, the effect burner 1 of this example will be described in detail.

As shown in FIGS. 1 and 3, the baffle plate 34 of the present example includes a lower plate 341 disposed on the outer periphery of the side surface portion 32 of the inner fuel nozzle 3 below the position where the side surface injection holes 321 are formed, and a side surface injection hole. And a side plate 342 disposed on the side of the formation position of 321. The baffle plate 34 has an L-shaped cross section with a lower plate 341 and a side plate 342.
Further, the side jet holes 321 and the baffle plate 34 are formed in a pair at positions facing each other in the side portion 32 of the inner fuel nozzle 3.

Also, as shown in FIG. 3, the plurality of upper surface ejection holes 311 in the inner fuel nozzle 3 of the present example is a first arrangement between the upper surface ejection holes 311 facing in one direction on the upper surface portion 31 of the inner fuel nozzle 3. The width W1 is narrower than the second arrangement width W2 between the upper surface ejection holes 311 in the direction orthogonal to the one direction.
The side ejection holes 321 and the baffle plate 34 are disposed on both sides in one direction forming the first array width W1 in the side surface portion 32 of the inner fuel nozzle 3.

As shown in FIG. 5, the inner fuel nozzle 3 is disposed at the upper end of the inner fuel supply pipe 33 through which the fuel gas F passes. The inner fuel supply pipe 33 is installed with its axial direction oriented in the vertical direction. The air draft tube 2 has a cylindrical shape (cylindrical shape in this example), and is disposed with its axial direction directed in the vertical direction.
As shown in FIGS. 1 and 4, the lower end opening 201 in the air draft pipe 2 is fixed to the inner fuel supply pipe 33. That is, the air draft pipe 2 is fixed to the outer periphery of the inner fuel supply pipe 33 by a plurality of connecting bars 23 disposed on the inner peripheral surface thereof. And the lower end opening part 201 for allowing the air A to pass through is formed between the some connection bars 23. FIG.

Further, as shown in FIG. 1, the air draft pipe 2 includes an annular first air passage 21 formed between the inner fuel nozzle 3 and a second air passage 22 formed above the first air passage 21. I have. The first air passage 21 has a straight shape with a uniform passage cross-sectional area, and the second air passage 22 has a flow of the air A passing through the second air passage 22 as a flow of the fuel gas F. In order to squeeze toward the center side, it has a tapered shape in which the cross-sectional area of the passage is reduced upward. With this tapered shape, the stationary production flame H1 can be formed in a triangular pyramid shape whose outer diameter decreases upward (see FIG. 7).
The first air passage 21 of this example has a straight shape in most parts, but a portion located at the upper end has a tapered shape in which the cross-sectional area of the passage decreases upward. .

In addition, by changing the taper angle of the second air passage 22, the length of the triangular flame-shaped production flame H1 can be changed.
Further, the upper end opening 202 in the air draft pipe 2 is disposed at a position protruding above the upper end surface 41 of the outer fuel nozzle 4.

  As shown in FIG. 9, the second air passage 22 in the air draft pipe 2 can be formed in a straight shape having a uniform passage cross-sectional area. In this case, the stationary production flame H1 can be formed in a cylindrical shape. Moreover, as shown with the broken line in the same figure, as for the 2nd air passage 22, most parts can also be made into a straight shape, and the part located in an upper end part can also be made into a taper shape.

  As shown in FIGS. 1 and 2, the outer fuel nozzle 4 has an annular shape (annular shape in this example) surrounding the outer periphery of the second air passage 22 in the air draft pipe 2. The outer ejection holes 411 of the present example are formed on a virtual circle centered on the central axis of the effect burner 1. Further, the outer ejection holes 411 of this example are formed in an array on two virtual circles having different diameters.

Further, the plurality of outer ejection holes 411 are formed to open obliquely outward in order to eject the fuel gas F obliquely outward. Further, the fuel gas F is ejected radially outward from the central axis of the effect burner 1.
An outer fuel supply pipe 43 for supplying fuel gas F to the outer fuel nozzle 4 is connected to the outer fuel nozzle 4.

  As shown in FIG. 2, the total opening area of the plurality of outer injection holes 411 in the outer fuel nozzle 4 is larger than the total opening area of the plurality of upper surface injection holes 311 in the inner fuel nozzle 3. Thus, even when the pressure of the fuel gas F supplied to the inner fuel nozzle 3 and the pressure of the fuel gas F supplied to the outer fuel nozzle 4 are substantially the same, the ejection of the fuel gas F ejected from the outer fuel nozzle 4 The amount can be made larger than the amount of fuel gas F ejected from the inner fuel nozzle 3.

Further, the amount of fuel gas F ejected from the outer fuel nozzle 4 can be 2 to 10 times the amount of fuel gas F ejected from the inner fuel nozzle 3. In this example, the ejection amount of the fuel gas F jetting from inner fuel nozzle 3 is set to about 0.04 m ³ / h, the ejection amount of the fuel gas F jetting from the outer fuel nozzle 4 is about 0.27 m ³ / h.

Further, as shown in FIG. 1, the inner fuel nozzle 3 includes a nozzle-side heater 51 on the outer periphery thereof. The nozzle-side heating heater 51 has a ring shape that covers the outer periphery of the inner fuel nozzle 3.
The air draft tube 2 includes a draft tube side heater 52 on the outer periphery thereof. The draft tube side heater 52 has an annular shape covering the outer periphery of the first air passage 21 in the air draft tube 2. Each of the nozzle side heater 51 and the draft tube side heater 52 is of a type that generates heat when energized. Moreover, the heating temperature by each heater 51,52 can be 150-180 degreeC.

  As shown in FIGS. 5 and 6, the fuel gas F ejected from the inner fuel nozzle 3 or the fuel gas F ejected from the outer fuel nozzle 4 is ignited around the upper end opening 202 in the air draft pipe 2. An ignition device 61 for performing the above is provided. In this example, the ignition device 61 is disposed above the outer fuel nozzle 4 in order to ignite the fuel gas F ejected from the outer fuel nozzle 4. The ignition device 61 of this example is a ceramic heater that generates heat when energized, and is configured to spontaneously ignite the fuel gas F.

Further, two ignition devices 61 are provided in order to prevent ignition failure. Moreover, the fuel gas F of this example is natural gas (city gas 13A).
The ignition device 61 can also be disposed above the inner fuel nozzle 3 in order to ignite the fuel gas F ejected from the inner fuel nozzle 3.

As shown in FIGS. 5 and 6, the effect burner 1 has a cover 7 that covers the air draft pipe 2 and the outer fuel nozzle 4. The cover 7 has a lower cover portion 71 that covers the lower portion of the air draft tube 2 and an upper cover portion 72 that covers the upper portion of the air draft tube 2 and the outer periphery of the outer fuel nozzle 4. Each of the lower cover portion 71 and the upper cover portion 72 has a cylindrical shape that allows the air A to pass from the lower opening toward the upper opening. In addition, the lower cover part 71 and the upper cover part 72 can be comprised by the member which has many holes, such as punching metal.
Further, the upper cover portion 72 is provided with an ultraviolet sensor 62 for monitoring the formation state of the flame.

  The production burner 1 of this example is configured such that combustion control is performed by a safe combustion control device (not shown). The safe combustion control device is configured to control the ejection timing and ejection time of the fuel gas F by the inner fuel nozzle 3 or the outer fuel nozzle 4 and the energization timing and energization time of the ignition device 61.

  As shown in FIG. 5, the inner fuel supply pipe 33 is provided with a first control valve 331 for opening and closing the inner fuel supply pipe 33. The outer fuel supply pipe 43 is provided with a second control valve 431 for opening and closing the outer fuel supply pipe 43. Then, when the safe combustion control device opens the first control valve 331, the fuel gas F is ejected from the inner fuel nozzle 3 to form a stationary production flame H1 (see FIG. 7).

On the other hand, when the safe combustion control device opens the first control valve 331 and the second control valve 431, the fuel gas F is ejected from the inner fuel nozzle 3 and the fuel gas F is ejected from the outer fuel nozzle 4. Thus, a lively effect flame H2 can be formed (see FIG. 8).
Further, the control of the combustion state in the production burner 1 of this example is performed by a program or a sequence circuit in the safe combustion control device.
When the control valves 331 and 431 can be adjusted in flow rate, the ejection amounts of the fuel gases F1 and F2 ejected from the fuel nozzles 3 and 4 can be appropriately adjusted.

  Further, as shown in FIGS. 7 and 8, according to the production burner 1 having the above-described configuration, the maximum cross-sectional outline of the lively effect flame H2 is 5 to 10 of the maximum cross-sectional outline of the stationary production flame H1. The maximum length of the live effect flame H2 can be formed to be 1.5 to 2.5 times the length of the stationary flame H1. In this example, a static flame H1 having a maximum cross-sectional outer shape of about 17 mm and a length of about 200 mm is formed, and the maximum cross-sectional outer shape is about 130 mm and the maximum length is about 400 mm. The state production flame H2 is formed.

Next, an operation for forming two types of production flames H1 and H2 using the production burner 1 will be described.
In this example, in order to ignite the fuel gas F ejected from the outer fuel nozzle 4, the live effect flame H2 is formed first, and then the stationary flame H1 is formed.
In addition, after the start of the combustion operation of the production burner 1, the nozzle side heating heater 51 and the draft tube side heating heater are used before the combustion operation is started in order to quickly stop the production flame H1 in a stationary state. 52 is energized to heat the effect burner 1.

  Then, when forming the dynamic flame for production H2, the safe combustion control device opens the second control valve 431, and the fuel gas F is obliquely upward from the plurality of outer ejection holes 411 in the outer fuel nozzle 4. Erupt towards. The ejected fuel gas F is ignited by the ignition device 61.

Further, when this ignition is performed, the safe combustion control device opens the first control valve 331 and ejects the fuel gas F upward from the plurality of upper surface ejection holes 311 in the inner fuel nozzle 3. At this time, due to the so-called draft effect, the air A in the air draft pipe 2 rises as the fuel gas F rises.
That is, the air A in the first air passage 21 in the air draft pipe 2 rises into the second air passage 22 with the upward flow of the fuel gas F, and the lower end opening 201 in the first air passage 21. Air A flows in. Then, the air A in the second air passage 22 rises at substantially the same speed as the fuel gas F rises.

Next, the fuel gas F ejected from the upper surface ejection hole 311 in the inner fuel nozzle 3 and flowing out from the upper end opening 202 in the air draft pipe 2 is combusted by the fuel gas F ejected from the outer ejection hole 411 in the outer fuel nozzle 4. It is ignited by the flame and burns.
At this time, an outer flame due to the combustion of the fuel gas F ejected from the outer ejection hole 411 is formed around the inner flame due to the combustion of the fuel gas F ejected from the upper surface ejection hole 311. Further, the outer flame is suppressed from being integrated with the inner flame by the air A rising at substantially the same speed as the rising speed (outflow speed) of the fuel gas F from the upper end opening 202. The outer flame is formed so as to move upward.

In addition, the entire flame by the inner flame and the outer flame is formed by a portion having a small cross-sectional outline and a portion having a large cross-sectional outline, and the portion having a large cross-sectional outline is repeatedly moved upward.
Thus, as shown in FIG. 8, the entire flame can form a production flame H <b> 2 in a state of dynamism toward the upper end opening 202 of the air draft pipe 2. In addition, in the same figure, the state where the production flame H2 moves is shown by a solid line and a broken line.
And this dynamic flame for production H2 can give an impression like a lively dynamic feeling to the viewer.

Next, when forming the stationary production flame H1, the safe combustion control device keeps the first control valve 331 open and ejects the fuel gas F from the inner fuel nozzle 3, The second control valve 431 is closed to stop the ejection of the fuel gas F from the outer fuel nozzle 4.
At this time, due to the so-called draft effect, the air A in the air draft pipe 2 rises as the fuel gas F and the combustion gas rise, and the fuel gas F and the combustion gas from the upper end opening 202 in the air draft pipe 2. The air A rises (outflows) at substantially the same speed as the rising speed (outflow speed).

In the air draft tube 2, the fuel gas F ejected from the upper surface ejection hole 311 in the inner fuel nozzle 3 burns while being surrounded by the air A.
Thus, as shown in FIG. 7, the flame caused by the combustion of the fuel gas F forms an effect flame H <b> 1 that is almost stationary from the inner fuel nozzle 3 to above the upper end opening 202 in the air draft pipe 2. Can do.
And this still-state production flame H1 can give an impression of a quiet feeling to the viewer.

  In addition, when the live effect flame H2 and the stationary flame H1 are formed, when the fuel gas F is ejected from the upper surface ejection hole 311 of the inner fuel nozzle 3, the inner fuel nozzle 3 The fuel gas F is also ejected from the side ejection holes 321. At this time, the fuel gas F ejected from the side ejection holes 321 is mixed with the air A rising in the air draft pipe 2 and burned to form a flame holding flame H3. The baffle plate 34 disposed on the outer periphery of the inner fuel nozzle 3 can prevent the air A rising in the air draft pipe 2 from directly colliding with the flame holding flame H3. Thereby, the flame H3 for flame holding can be formed stably.

  Further, by forming the flame holding flame H3 in the air draft tube 2, when forming the production flames H1 and H2, the fuel gas F is prevented from performing lift combustion, and each production flame H1. , H2 can be prevented from being formed at a predetermined distance from the upper end opening 202 of the air draft tube 2. Thereby, the combustion in the production burner 1 can be stabilized, and the production flames H1 and H2 can be formed stably.

Thereafter, the safe combustion control device can burn the fuel gas F at an appropriate timing and repeatedly form a lively effect flame H2 and a stationary effect flame H1.
Further, when the fuel gas F ejected from the inner fuel nozzle 3 is ignited, the production flame H1 in the stationary state can be formed first, and then the production flame H2 in the dynamic state can be formed. .

Thus, the production burner 1 can express a sense of silence by forming the stationary production flame H1, and expresses a dynamic feeling by forming the dynamic production flame H2. can do.
Therefore, according to the production burner 1 of the present example, it is possible to stably form the production flame H1 in the stationary state and the production flame H2 in the dynamic state, and the production effect by each production flame is further emphasized. be able to.

Cross-sectional explanatory drawing which shows the burner for production | presentation in an Example. The top view which shows the burner for production | presentation in the state seen from the X arrow direction in FIG. Sectional explanatory drawing which shows the burner for production | presentation in the state seen from the YY arrow gaze direction in FIG. Sectional explanatory drawing which shows the burner for production | presentation in the state seen from the ZZ arrow line direction in FIG. Cross-sectional explanatory drawing which shows the state which attached the cover etc. to the burner for production | presentation in an Example. The top view which shows the state which attached the cover etc. to the burner for production | presentation in an Example. Cross-sectional explanatory drawing which shows the burner for production | presentation of the state which formed the flame for production | presentation of the stationary state in an Example. Sectional explanatory drawing which shows the burner for production | presentation of the state which formed the flame for production of the lively state in an Example. Cross-sectional explanatory drawing which shows the other burner for effects in an Example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Production burner 2 Air draft pipe 201 Lower end opening 202 Upper end opening 3 Inner fuel nozzle 31 Upper surface part 311 Upper surface ejection hole 32 Side surface part 321 Side ejection hole 34 Baffle plate 4 Outer fuel nozzle 411 Outer ejection hole H1 Production of stationary state Flame H2 Flame for production in dynamic state H3 Flame holding flame F Fuel gas A Air

Claims (4)

An air draft tube for passing air from the lower end opening to the upper end opening;
An inner fuel nozzle that is disposed inside the air draft pipe and ejects fuel gas;
The inner fuel nozzle has a plurality of upper surface ejection holes for ejecting the fuel gas formed on the upper surface portion, and a side ejection hole for ejecting the fuel gas formed on the side surface portion. And a baffle plate surrounding the lower side and the side of the formation side of the side surface ejection hole on the outer periphery of the side surface part,
Combusting the fuel gas ejected from the side ejection holes to form a flame-holding flame, and combusting the fuel gas ejected from the upper surface ejection holes to form the upper end opening of the air draft pipe An effect burner, characterized in that the effect flame is formed in a stationary state toward the upper side.   2. The baffle plate according to claim 1, wherein the baffle plate includes, on the outer periphery of the side surface portion, a lower plate disposed below the position where the side surface ejection holes are formed, and a side portion disposed lateral to the position where the side surface ejection holes are formed. An effect burner characterized by having an L-shaped cross section with a plate.   3. The effect burner according to claim 1, wherein the side surface ejection hole and the baffle plate are formed as a pair at positions facing each other. The outer fuel nozzle for injecting fuel gas is arrange | positioned in the outer side of the said air draft pipe in any one of Claims 1-3, This outer fuel nozzle is the said upper surface part. A plurality of outer ejection holes for ejecting fuel gas are formed,
The fuel gas ejected from the upper surface ejection hole is combusted and the fuel gas ejected from the outer ejection hole is combusted so as to move upward above the upper end opening of the air draft pipe. A burner for production characterized by forming a flame for production.

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