KR101221818B1 - Burner for ranges - Google Patents

Abstract

[assignment]
It is provided with two upper and lower flame ports formed on the outer circumferential surface of the burner head 3 provided on the burner body 2, and supplies gas only to the lower flame port 4L and the upper flame port 4U. It is a furnace burner which enables the state transition between the supplying states and the fire transition from the lower fireball to the upper fireball by initiating the gas supply to the upper fireball, and prevents backfire when the fire is transferred to the upper fireball. It is also possible to avoid loud ignition.
[Resolution]
A part of the lower fireball 4L is a flame transition fireball 4La whose up-down direction is larger than the other lower fireball, and the upper end is located above the upper end of the other lower fireball. The vertical distance LH between the upper end of the flame transition flame opening 4La and the lower end of the upper flame opening 4U is 2.5 times or less than the vertical dimension Lh of the flame transition flame opening 4La, It is set to the distance which can prevent flame transfer to the upper flame opening 4U before the actual amount of ejected gas from the upper flame opening 4U becomes more than a predetermined amount necessary for the backfire prevention.

Description

BURNER FOR RANGES {BURNER FOR RANGES}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a stove burner having two upper and lower flame openings formed on an outer circumferential surface of a burner head provided on a burner body.

As a conventional burner for this kind of furnace, it is possible to switch the state between supplying gas only to the lower fireball and gas supply to the upper fireball, and to start the gas supply to the upper fireball to the lower fireball. It is known that the flame transition is carried out to an upper flame | bulb from the back (for example, refer patent document 1). In this burner, there is an advantage in that the fire power can be controlled in a wide range from a weak fire burned only by the lower fireball to a strong fire burned by both the fireballs in the lower and upper layers.

Herein, Patent Document 1 describes that the vertical distance between the lower fireball and the upper fireball is not less than three times the vertical dimension of the lower fireball so that the fire power to the object to be heated can be weakened as much as possible when burning only with the lower fireball. The position of the lower fireball is set as low as possible. However, in this case, when the gas supply to the upper fireball is started, the flame transition is delayed to the upper fireball, and a large amount of gas emitted from the upper fireball is ignited at the same time, so that a large ignition sound is generated. It is easy to occur.

In order to relieve this unfavorable condition, a part of the lower fireball has a flame transition fireball in which the vertical dimension is larger than the other lower fireball and the upper part is located above the upper part of the other lower fireball. It is conceivable that the flame war is rapidly transferred from the fireball to the fireball of the upper fireball as the fire extinguishing. However, it was found that when the flame transition is provided with the fireball and the flame is rapidly transferred to the upper fireball, backfire in the upper fireball occurs easily. In other words, even when the gas supply to the upper fireball is increased to a predetermined amount necessary to prevent backfire at the upper fireball when the gas is supplied to the upper fireball, it takes some time until the amount of gas ejected from the upper fireball increases to the predetermined amount. This takes Therefore, if the flame transitions from the lower fireball before the actual amount of blown gas from the upper fireball increases to a predetermined amount, the combustion speed is faster than the gas blowing rate from the upper fireball, and backfire occurs.

Japanese Patent No. 3586974 (Fig. 3)

DISCLOSURE OF THE INVENTION In view of the above, it is an object of the present invention to provide a furnace burner which can prevent backfire when a flame transitions from a lower fireball to an upper fireball, and does not generate a large ignition sound.

In order to solve the above problems, the present invention is provided with two upper and lower flame openings formed on the outer circumferential surface of the burner head installed on the burner body, and the lower flame It is possible to switch the state between supplying gas only to the bulb and supplying gas to the upper fireball, and flame transition from the lower fireball to the upper fireball by initiating gas supply to the upper fireball. In a burner for a furnace, a portion of the lower fireball is larger than the other lower fireball, and the upper flame is located above the upper part of the lower fireball. The vertical distance between the top of the flame transition fireball and the bottom of the upper fireball is the vertical dimension of the flame transition fireball. In the range of 2.5 times or less, prevents the flame transition from the fireball to the fireball before the actual amount of gas emitted from the upper fireball is greater than or equal to the predetermined amount required to prevent backfire in the fireball. It is characterized in that it is set to the distance which can be made.

If the vertical distance between the upper end of the fireball and the lower part of the upper fireball is too short, the amount of gas supplied to the upper fireball may be increased to a predetermined amount necessary to prevent backfire at the upper fireball when gas is supplied to the upper fireball. However, there is a risk that the flame transition occurs from the flame transition from the fireball to the upper flameball before the actual blown gas amount from the upper flameball becomes a predetermined amount or more. On the other hand, in the present invention, the vertical distance between the upper end of the flame transition fireball and the lower end of the upper fireball is from the flame transition fireball before the actual amount of ejected gas from the upper fireball becomes more than a predetermined amount necessary to prevent backfire in the upper fireball. Since it is set to a distance that can prevent the flame war to the upper fireball, it is possible to prevent backfire during the flame war. In addition, if the vertical distance is 1.5 times or more of the vertical dimension of the flame transition fireball, the upper flame is discharged from the flame transition fireball before the actual amount of ejected gas from the upper fireball becomes more than a predetermined amount necessary to prevent backfire in the upper fireball. It is possible to prevent the flame transfer to the sphere. In addition, when the vertical distance exceeds 2.5 times the vertical dimension of the flame transition flameball, the flame transition is excessively delayed to the upper flameball, and a large ignition sound occurs by igniting a large amount of gas emitted from the upper flameball at once. There is concern. In contrast, in the present invention, since the vertical distance is set to 2.5 times or less of the vertical dimension of the flame transition flameball, the flame transition does not occur excessively to the upper flameball, so that a large ignition sound does not occur.

In addition, it is only a part of the lower fireball that the flame transition having a larger vertical dimension is used as the fireball, and the position of the upper portion of the lower fireball other than the flameball can be sufficiently low without considering the flame transition to the upper fireball. Therefore, it is possible to sufficiently weaken the fire power for the object to be heated when burning only with the lower fireball, thereby ensuring a wider control range of the fire power.

Moreover, in this invention, you may provide the overhang surface which extends radially outward from the upper end of a flame opening and faces downward on the outer peripheral surface of a burner head. If the overhang surface extends radially outward with respect to the upper end of the flame transition fireball, the flame rises in the fireball when the flame transition is set to 1/3 or more times the vertical dimension of the flame transition fireball. Even if the vertical distance is set to be less than 1.5 times the vertical dimension of the flame transition fireball, the actual blowing gas from the upper fireball is not less than a predetermined amount necessary to prevent backfire in the upper fireball. It is possible to prevent the flame transition from the fireball to the upper fireball. Shortening the vertical distance here is advantageous because it helps to increase the vertical dimension of the upper fireball to increase the fire power in a strong fire. In addition, if the amount of extension extending radially outward with respect to the upper end of the flame transition fireball on the overhang surface exceeds 1 times the vertical dimension of the flame transition fireball, a defect occurs in the flame transition to the upper fireball. It should be set to 1/3 to 1 times the vertical dimension of transition fireball.

In addition, it is located in a direction corresponding to a plurality of Ode poles of Odeok (五 德, which means 'an iron rod on which a heated object such as a pot is placed') placed on the top plate of a stove. When the circumferential plural places of the burner head are used as the Odepole mating portion, and the upper fireball is formed at the Odepole mating portion, the flame generated from the upper fireball contacts the Odepole and incomplete combustion do. For this reason, it is preferable to form only the lower flame | ball hole without forming an upper flame | ball hole in each Odepole mating part. In addition, the up-down direction dimension of the lower flame | spherical flame opening formed in the mating part of a solenoid pole needs to be made comparatively small so that a flame may not contact a solenoid pole. For this reason, when burning with only the lower flame ball, the amount of heat generated in the mating portion of the sole is lower than that of the other portions, resulting in uneven heat distribution. If a flame transition fireball is formed in the circumferential portion adjacent to each of the ridge poles, the calorific decrease in the ridge poles is compensated by the large flames generated by the flame hole, and the fireball is burned only by the lower fireball. The heat distribution can be made uniform.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a sectional view of a furnace equipped with a furnace burner of a first embodiment of the present invention.
Fig. 2 is a perspective view of the furnace burner of the first embodiment.
3 is a side view of the main portion of the furnace burner of the first embodiment.
4 is a cross-sectional view taken along line IV-IV of FIG. 3.
5 is a graph showing the change characteristics of the amount of gas supplied to the lower and upper fireballs.
Fig. 6 is a sectional view corresponding to Fig. 4 of the furnace burner of the second embodiment.
Fig. 7 is a sectional view corresponding to Fig. 4 of the furnace burner of the third embodiment.

Referring to FIG. 1, A is a furnace body, B is an upper plate covering the upper surface of the furnace body A, and the furnace burner 1 is provided through the burner opening B1 formed in the upper plate B. As shown in FIG. In addition, on the upper plate B, a dent C which mounts a to-be-heated object such as a pot heated by the burner 1 so as to surround the burner opening B1 is placed. In addition, the Odeok (C) is composed of an annular Odeok frame (C1) and a plurality of Odeok pole (C2) provided radially to the Odeok frame (C1). .

The burner 1 has a burner body 2 inserted into the burner opening B1 and a burner head 3 on the burner body 2. On the outer circumferential surface of the burner head 3, as shown in FIG. In addition, the part of the circumferential direction of burner head 3 located in the direction corresponding to the some dent pole C2 of the dent C is made into the dent pole mating part 3a. In order to prevent incomplete combustion due to flame contacting the sole pole pole C2, only the lower flame hole 4L is formed without forming the upper fire sphere 4U.

The burner body 2 is comprised by the outer cylinder 21, the intermediate cylinder 22, and the inner and outer three layers of the cylinder 23 inside. The outer cylinder 21 is provided with a skirt portion 21a which is arranged downward from the outer periphery of the upper end portion thereof. Then, a covering (D) covering the burner opening (B1) of the upper plate (B) is inserted into the skirt portion (21a), so that boiling broth is invaded from the burner opening (B1) by the covering (D). It can prevent it. In addition, the projection C3 is formed at one or more places in the circumferential direction of the inner circumference of the duct frame C1 to the outer circumference of the covering D as well as the projection C3. The notch (D1) to which () couple | bonds is formed, and it is possible to phase-determine the sole C.

The burner head 3 has an annular lower head member 31 having a cylindrical portion 31a vertically provided at its inner circumference with an intermediate cylinder 22 of the burner body 2 and a lower surface of the burner body 2. It consists of the disk-shaped upper head member 32 which installed the cylinder part 32a which engages with the inner cylinder 23 perpendicularly. An upper annular wall 33 on which the upper head member 32 is seated is provided on the outer periphery of the upper surface of the lower head member 31. The upper annular wall 33 is provided with many groove | channels which become the upper flame opening 4U recessed downward from the upper end surface at intervals of the circumferential direction. And the upper end of these groove | channel is closed by the upper head member 32, and the upper flame opening 4U is comprised between the lower head member 31 and the upper head member 32. As shown in FIG.

In addition, a lower annular wall 34 seated on the upper end of the outer cylinder 21 of the burner body 2 is vertically installed on the outer periphery of the lower head member 31. It is. The lower annular wall 34 is provided with many groove | channels which become 4L of lower-layer flame openings recessed upward from the lower end surface at intervals of the circumferential direction. And the lower end of these groove | channel is closed by the upper end of the outer cylinder 21, and the lower flame flame 4L is comprised between the burner body 2 and the lower head member 31. As shown in FIG.

In addition, as shown in FIG. 3, there are a plurality of types of fireballs having different up and down direction dimensions as shown in FIG. The lower flame ball 4L formed in each of the ridge pole matching portions 3a is made to have a relatively small vertical dimension in order to prevent the flame from contacting the ridge pole C2, and the ridge pole matching portion 3a. In the circumferential portion between), a lower flame ball 4L having a larger vertical dimension is formed. In addition, since the combustibility deteriorates when such a large lower fireball 4L is continuously formed, the lower fireball 4L having a larger up-down direction dimension and the small lower fireball 4L are alternately formed.

In addition, the lower flame ball 4L formed in the circumferential portion adjacent to each Odepole mating portion 3a has the largest vertical dimension, and the upper end is located above the upper end of the other lower flame ball 4L. It is assumed that the flame war is the fireball 4La. Specifically, the up and down direction dimension of the lower layer flame ball 4L other than the flame transition flame port 4La is made smaller than the up and down direction dimension of the lower annular wall 34, and the up and down direction dimension of the flame transition flame port 4La is lower side. It is made to be equal to the vertical dimension of the annular wall 34. In addition, a portion between the upper flame opening 4U and the lower flame opening 4L of the outer circumferential surface of the burner head 3, that is, the outer circumferential surface portion of the lower head member 31 between the upper annular wall 33 and the lower annular wall 34. The extension part 35 extended slightly in the radial direction outer side is formed.

The burner 1 further includes a first mixed pipe 5U for the upper flame port 4U communicating with a space between the intermediate cylinder 22 and the inner cylinder 23 of the burner body 2, A second mixing pipe 5L for the lower flame port 4L communicating with the space between the outer cylinder 21 and the intermediate cylinder 22 of the burner body 2 is provided. Referring to FIG. 2, fuel gas is supplied to the first mixing pipe 5U through a first branch passage 6U branched from a common gas supply passage 6U. The fuel gas is supplied to the second mixing pipe 5L through the second branch passage 6L branched from the gas supply passage 6. Then, the fuel gas and the primary air sucked into each of the mixing tubes 5U and 5L are mixed in the first and second mixing tubes 5U and 5L, and the mixed gas from the first mixing tube 5U is mixed. It blows out from the upper flame opening 4U through the space between the intermediate cylinder 22 and the inner cylinder 23 of the burner body 2, and the space between the lower head member 31 and the upper head member 32. The mixed gas from the two mixing pipes 5L is lowered through the space between the outer cylinder 21 and the intermediate cylinder 22 of the burner body 2 and the space between the outer cylinder 21 and the lower head member 31. It is made to eject from the flame | bulb 4L.

The gas supply passage 6 is provided with a main valve 7 which is opened at the time of ignition and closed at the time of fire extinguishing. The levers and knobs for thermal control not shown in the drawings are shown in the first and second branch passages 6U and 6L. The first and second flow rate regulating valves 8U and 8L are inserted into and interlocked with the operation member made of the first and second openings. The operation member is operable to operate from a weak fire position to a strong fire position. When the operation member is operated from the weak fire position to the strong fire position, the opening degree of the second flow control valve 8L gradually increases from the minimum opening degree. Then, the supply gas amount to the lower fireball 4L gradually increases from QLmin, which is a predetermined minimum amount necessary for preventing backfire at the lower fireball 4L, as indicated by a line in FIG. On the other hand, the first flow control valve 8U is not opened until the operation member reaches a predetermined intermediate position, but if it exceeds the intermediate position, the first flow control valve 8U is suddenly opened to a predetermined degree and then opened to a strong fire position thereafter. Gradually increases. When the operating member is operated from the weak fire position to the strong fire position, gas is not supplied to the upper flame opening 4U until it reaches the intermediate position as indicated by line b in FIG. The amount of gas supplied to the fireball 4U rapidly increases to QUmin, which is a predetermined minimum amount necessary for preventing backfire at the upper fireball 4U, and then gradually increases to the maximum amount QUmax.

Specifically, when the total area of the lower fireball 4L is 163.5mm ² and the total area of the upper fireball 4U is 256.6mm ² , the QLmin is 330 kcal / h (the fireball load is 2.0 kcal / h / mm ² ), QLmax is 740 kcal / h (fireball load 4.5 kcal / h / mm ² ), QUmin is 850 kcal / h (fireball load 3.3 kcal / h / mm ² ), and QUmax is 3810 kcal The / h (fireball load is set at 14.8 kcal / h / mm ² ).

In the case of burning even in the upper fireball 4U, the operation member is operated to the strong fire position beyond the intermediate position until the flame war is transferred from the fireball 4La to the upper fireball 4U. When the intermediate position is exceeded, the amount of gas supplied to the upper fireball 4U rapidly increases to QUmin, but it takes some time until the actual amount of gas ejected from the upper fireball 4U increases to QUmin. As a result, until the operating member reaches the position indicated by c of FIG. 5 in which the operation member is displaced by a certain amount from the intermediate position to the strong fire position, the actual amount of ejected gas from the upper flame opening 4U does not increase to QUmin in a very short time. Will not. If the flame transition from the flame transition 4La to the upper flame 4U before the actual amount of ejected gas from the upper flame 4U is greater than or equal to QUmin, the combustion rate is higher than the rate of gas ejection from the upper flame 4U. It is faster and causes backfire.

Wherein LH <1.5Lh, the upper and lower distance between the upper end of the flame transition flame opening (4La) and the lower end of the upper flame opening (4U) is LH and the vertical dimension of the flame transition flame opening (4La) is Lh. From the flame transition flame opening 4La before reaching the position c in FIG. 5, i.e., before the actual amount of ejected gas from the upper flame opening 4U becomes more than QUmin. There is a risk of backfire due to flame transition to the upper fireball 4U. On the other hand, if LH≥1.5Lh, it is possible to prevent the flame transition from the flame transition flame port 4La to the upper flame port 4U before the actual amount of ejected gas from the upper flame port 4U becomes more than QUmin, resulting in backfire. It was confirmed experimentally not. If LH> 2.5Lh, the flame transition to the upper fireball 4U is excessively delayed, and there is a fear that a large ignition sound may be generated by igniting a large amount of gas emitted from the upper fireball 4U at one time. On the other hand, when LH≤2.5Lh, it was also confirmed experimentally that the flame transition to the upper flame ball 4U was not excessively delayed and no large ignition sound was generated. Therefore, in order to prevent the backfire and the generation of a large ignition sound when the flame transition is carried out from the fireball 4La to the upper fireball 4U, it is necessary to set 1.5Lh ≦ LH ≦ 2.5Lh. In this embodiment, LH is set to about 2 Lh.

In addition, in the present embodiment, the flame transition flame ball 4La having a large up-down direction dimension is only a part of the lower flame ball 4L, and the upper portion of the lower flame ball 4L other than the flame transition flame ball 4La. The position can be made low enough without considering the flame transition to the upper fireball 4U. Therefore, when burning only with the lower flame ball 4L, the fire power for the object to be heated can be sufficiently weakened, so that the control range of the fire power can be secured widely.

In addition, since the up and down direction of the lower flame ball 4L formed in the sole portion 3a is relatively small, the amount of heat generated in the sole portion 3a when burning with only the lower flame ball 4L is different. It is lowered compared to the part. However, in the present embodiment, since the flame transition flame openings 4La are formed at both circumferential portions adjacent to each of the ridge pole matching portions 3a, the calorific decrease in the ridge pole matching portions 3a is reduced by the flame transition flame openings ( It is supplemented by a large flame generated at 4La), and even when burning only with the lower flame ball 4L, the heat distribution can be equalized.

Next, a second embodiment shown in FIG. 6 and a third embodiment shown in FIG. 7 will be described. The basic structure of each of the second and third embodiments is the same as that of the first embodiment, and the same reference numerals are given to the same members as the first embodiment.

The difference from the first embodiment of the second embodiment is that the lower outer circumferential surface (outer circumferential surface of the lower annular wall 34) of the burner head 3 in which the lower-layer fireball 4L is formed is offset radially inwardly than the first embodiment. (offset), an overhang surface 36 extending downward from the upper end of the flame opening 4La and extending radially outward is formed. The difference from the first embodiment of the third embodiment is that the outer diameter of the extension part 35 formed on the outer peripheral surface portion of the lower head member 31 between the upper annular wall 33 and the lower annular wall 34 is reduced. It is larger than the first embodiment, and the overhang surface 36 extending downward from the upper end of the flame port 4La in the radial direction and facing downward is formed.

According to the second and third embodiments, the rise of the flame generated by the overhang surface 36 in the flame opening 4La can be suppressed. For this reason, the vertical distance LH between the upper end of the flame transition fireball 4La and the lower end of the upper fireball 4U is less than 1.5 times the vertical dimension Lh of the flame transition fireball 4La, for example, 1.3. Even if it is set to Lh, it is possible to prevent the flame transition from the upper flame opening 4U to the upper flame opening 4U before the actual amount of ejected gas from the upper flame opening 4U becomes more than QUmin, so that no flameback occurs when the flame is transferred. In addition, shortening the LH is advantageous because it helps to increase the vertical force of the upper flame ball 4U in order to increase the fire power at the strong fire position.

In addition, when the overhang surface 36 extends radially outward with respect to the upper end of the flame transition flame opening 4La, and R <Lh / 3, the flame transition occurs at the flame transition flame opening 4La. It is impossible to suppress the rise of the flame, and if LH <1.5Lh is set, there is a fear that backfire occurs during flame transition. If R> Lh, the flame transition to the upper flame ball 4U is poor. Therefore, it is preferable to set Lh / 3? R? Lh. In the second and third embodiments, R is set to about 0.7 Lh.

A: cooker body
B: tops
C: Oduck
C2: Odepole
1: stove burner
2: burner body
3: burner head
3a: Odepole mating part
36: overhang
4U: Upper Fireball
4L: Lower Fireball
4La: Flame Transition Fireball
LH: The vertical distance between the top of the flame transition fireball and the bottom of the upper fireball
Lh: Vertical dimension of flame transition fireball
R: Extension amount of overhang surface

Claims (4)

The upper and lower two flame openings are formed on the outer circumferential surface of the burner head installed on the burner body, and the gas is supplied only to the lower flame opening and the upper flame. In the furnace burner which makes it possible to switch the state between the gas supply state and the flame transition from the lower fireball to the upper fireball by initiating the gas supply to the upper fireball,
Some of the lower fireballs shall be flameballs whose up and down directions are larger than the other lower fireballs, and whose upper ends are located above the upper ends of the other lower fireballs.
The vertical distance between the top of the fireball and the bottom of the fireball is 2.5 times or less of the up and down dimensions of the fireball, so that the actual amount of gas emitted from the fireball is higher than that of the fireball. A burner for a stove, characterized in that the flame war is set to a distance that can prevent the flame war from the fireball to the upper fireball before the predetermined amount required for fire extinguishing.
The method of claim 1,
The up and down distance is a furnace burner, characterized in that it is set to 1.5 to 2.5 times the vertical dimension of the flame transition flame ball.
The method of claim 1,
On the outer circumferential surface of the burner head, an overhang surface is formed which extends radially outward from the top of the flame transition fireball and faces downward, and the overhang surface is radially outer with respect to the top of the flame transition fireball. The length of the extension is set to 1/3 to 1 times the vertical dimension of the flame transition fireball, and the vertical distance is shorter than 1.5 times the vertical dimension of the flame transition fireball. Dragon burner.
4. The method according to any one of claims 1 to 3,
A portion of the circumferential plural places of the burner head, which is located in a direction corresponding to a plurality of Ode poles of Ode placed on the top plate of the furnace, The pole flames are formed, and each of the ridge poles is formed without forming the upper flame balls, and only the lower flame balls are formed, and the flame transition flames are formed in the circumferential portion adjacent to each of the ridge poles. Furnace burner, characterized in that.

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