JP2014134337A - Burner nozzle and flame detecting structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To properly detect flame while detecting the flame formed by gases injected from a premixed gas jetting portion and a fuel gas jetting portion with a simple constitution.SOLUTION: A nozzle body 12 includes a premixed gas jetting portion 13 for jetting a premixed gas G1 obtained by mixing combustion air with a fuel gas, a fuel gas jetting portion 14 for jetting the fuel gas G2 to the circumference of the premixed gas jetting portion 13, a premixed gas supply passage 15 for supplying the introduced premixed gas G1 to the premixed gas jetting portion 13, a fuel gas supply passage 16 for supplying the introduced fuel gas G2 to the fuel gas jetting portion 14, and a communicating portion K for communicating an intermediate region of the premixed gas supply passage 15 and an intermediate region of the fuel gas supply passage 16.

Description

  The present invention includes a premixed gas ejection portion that ejects a premixed gas in which combustion air and fuel gas are mixed, and a fuel gas ejection portion that ejects fuel gas around the premixed gas ejection portion. The present invention relates to a burner nozzle and a flame detection structure of a burner to which the burner nozzle is attached.

  The burner nozzle as described above is used in, for example, a burner provided in a radiant tube, and a premixed gas ejection portion is provided at the center of the nozzle body, and in a circumferential direction surrounding the premixed gas ejection portion. A plurality of fuel gas ejection portions are provided at intervals. A premixed gas pipe and a fuel gas pipe are connected to the nozzle body, a premixed gas supply path for supplying the premixed gas introduced by the premixed gas pipe to the premixed gas ejection section, and a fuel A fuel gas supply path for supplying the fuel gas introduced through the gas pipe to the fuel gas ejection section is provided (for example, see Patent Document 1).

JP-A-6-117612

  As the burner nozzle as described above, for example, as shown in FIGS. 7 and 8, a premixed gas supply path 105 and a fuel gas supply path 106 are completely separated and formed.

  In this burner nozzle, a premixed gas ejection portion 101 is provided at the center of the tip of the nozzle body 100, and a fuel gas ejection portion 102 is provided on the proximal end side of the nozzle body 100 with respect to the premixed gas ejection portion 101. A plurality of fuel gas ejection portions 102 are provided at intervals in the circumferential direction surrounding the periphery of the premixed gas ejection portion 101. Then, the fuel gas G2 is ejected from the surroundings to the premixed gas G1 ejected from the premixed gas ejecting portion 101 by the plurality of fuel gas ejecting portions 102. Combustion air A is supplied from the periphery of the fuel gas ejection portion 102.

  In this burner nozzle, a cylindrical first flow path portion 107 and a cylindrical second flow path portion 108 are provided in order from the base end side of the nozzle body 100. The first flow path portion 107 and the second flow path portion are provided. A central axis with the portion 108 is provided concentrically. The first flow path portion 107 is formed in a straight line extending in the axial direction of the nozzle body 100 with the same flow path diameter. The second flow path portion 108 is formed such that the flow path diameter at the proximal end thereof is smaller than the flow path diameter of the first flow path portion 107, and the first flow path portion 107 and the second flow path portion 108 are A step is formed between them. The second flow path part 108 is formed in a divergent shape so that the diameter of the flow path becomes larger toward the tip side. Further, the nozzle body 100 is provided with a third flow path portion 109 that extends from the first flow path portion 107 to the outside in the radial direction and communicates the first flow path portion 107 and the fuel gas ejection portion 102. The premixed gas pipe 103 is provided with a swivel unit 110 for swirling and flowing the premixed gas G1.

  The gas pipe connected to the nozzle body 100 has a double pipe structure in which the premixed gas pipe 103 that supplies the premixed gas G1 is the inside and the fuel gas pipe 104 that supplies the fuel gas G2 is the outside. The premixed gas pipe 103 is connected in a state protruding from the fuel gas pipe 104 to the tip side of the nozzle body 100. The leading end of the premixed gas pipe 103 is fitted into the proximal end of the second flow path part 108, and the leading end of the fuel gas pipe 104 is the proximal end of the first flow path part 107. It is screwed and connected in a state of being fitted into the end. Thus, the first flow path portion 107 is partitioned into an inner space and an outer space by the premix gas pipe 103, and the premix gas supply path 105 and the fuel gas supply path 106 are formed separately. .

  That is, the premixed gas G1 is introduced into the second flow path part 108 through the premixed gas pipe 103, and is supplied to the premixed gas ejection part 101 through the second flow path part 108, so that the premixed gas supply The path 105 is constituted by the second flow path part 108. Further, the fuel gas G2 is introduced into the first flow path part 107 through the fuel gas pipe 104, and the introduction part becomes an outer space partitioned by the premixed gas pipe 103 in the first flow path part 107. ing. The fuel gas G2 is supplied to the fuel gas ejection portion 102 through the outer space in the first flow path portion 107 and the third flow path portion 109, and the fuel gas supply path 106 is connected to the first flow path portion. 107 and a third flow path portion 109.

  As a flame detection structure of a burner equipped with such a burner nozzle, flame detection for premixed gas for detecting a flame formed by the premixed gas G1 ejected from the premixed gas ejection section 101, and fuel gas ejection Two flame detections, namely, a flame detection for a fuel gas that detects a flame formed by the fuel gas G2 ejected from the unit 102, are performed separately. Incidentally, in this way, flames that may be formed independently, such as gas nozzles in which the premixed gas supply channel and the fuel gas supply channel are completely separated and formed, can be detected individually. Because it is needed.

  Specifically, when performing the flame detection for the premixed gas and the flame detection for the fuel gas separately, for example, for the flame detection for the premixed gas, a viewing window is provided at the base end of the premixed gas pipe 103. Etc., by detecting the flame for the premixed gas visually by the operator, or by providing a flame detection sensor such as a flame rod at the flame formation position formed by the premixed gas. Flame detection will be performed. In addition, regarding the flame detection for the fuel gas, the flame detection for the fuel gas is performed by providing a flame detection sensor such as a frame rod at the flame forming position.

  However, in the flame detection structure as described above, the flame detection structure for the premixed gas and the flame detection structure for the fuel gas must be provided separately, and there is a possibility that the configuration becomes complicated accordingly. In the gas nozzle described above, the flame formed by the premixed gas and the flame formed by the fuel gas are formed close to each other, so that the flame is formed by the premixed gas and the fuel gas. Even if only one of the flames to be detected is detected, it is formed not only by one of the flame formed by the premixed gas and the flame formed by the fuel gas but by the premixed gas due to the fluctuation of the flame. There is a possibility of false detection, such as detecting both or the other of the flame and the flame formed by the fuel gas. In addition, as described above, when a flame detection sensor is provided at the flame forming position as the fuel gas flame detection structure, it is difficult to secure a space for installing the flame detection sensor.

  The present invention has been made paying attention to such a point, and its purpose is to perform detection of a flame formed by the gas ejected from the premixed gas ejection portion and the fuel gas ejection portion with a simple configuration, It is in providing a burner nozzle capable of appropriately performing the flame detection and a flame detection structure of the burner to which the burner nozzle is attached.

  In order to achieve this object, the characteristic configuration of the burner nozzle according to the present invention is that a premixed gas injection portion for injecting a premixed gas in which combustion air and fuel gas are mixed into the nozzle body, and the premixed gas. A fuel gas ejection section for ejecting fuel gas around the ejection section, a premixed gas supply path for supplying the premixed gas to be introduced to the premixed gas ejection section, and a fuel gas ejection for introducing the introduced fuel gas A fuel gas supply path to be supplied to the unit, and a communication part that communicates the intermediate part of the premixed gas supply path and the intermediate part of the fuel gas supply path.

  According to this characteristic configuration, by providing the communication part, gas mixing for mixing a part of the premixed gas supplied in the premixed gas supply path to the fuel gas supply path through the communication part, and the fuel gas supply path Thus, at least one gas mixing with the gas mixing in which a part of the fuel gas supplied in this manner is mixed into the premixed gas supply path through the communication portion occurs. As described above, the premixed gas and the fuel gas are mixed by the communicating portion, and the mixed gas is ejected from one or both of the premixed gas ejection portion and the fuel gas ejection portion to form a flame and burn. Can do. From this, the flame formed by the mixed gas can be considered as substantially one flame formed by the gas ejected from the premixed gas ejection portion and the fuel gas ejection portion. Therefore, as flame detection, it is only necessary to detect a flame formed by the mixed gas. And since the mixed gas of the premixed gas and the fuel gas is ejected from one or both of the premixed gas ejection section and the fuel gas ejection section, a flame formed by the mixed gas is detected. The flame detection can be performed with a simple configuration. Moreover, the flame detection target is not only one of the flame formed by the premixed gas and the flame formed by the fuel gas, but is ejected from one or both of the premixed gas ejection portion and the fuel gas ejection portion. Therefore, even if a flame fluctuation or the like occurs, it is possible to appropriately detect the flame.

  According to a further feature of the burner nozzle according to the present invention, the premixed gas supply path includes a premixed gas introduction part into which the premixed gas is introduced by a premixed gas pipe, and the fuel gas supply path is A fuel gas introduction part for introducing fuel gas in a fuel gas pipe, wherein the premix gas pipe and the fuel gas pipe are connected to the nozzle body with respect to the premix gas introduction part and the fuel gas introduction; It is comprised so that connection is possible in the state which forms the communication space which communicates between the parts, and the communication part is formed in the communication space.

  According to this characteristic configuration, a part of the premixed gas introduced into the premixed gas introduction portion is fuel gas by the communication space formed by connecting the premixed gas pipe and the fuel gas pipe to the nozzle body. At least one gas mixture of the gas mixture to be mixed in the introduction portion and the gas mixture in which a part of the fuel gas introduced into the fuel gas introduction portion is mixed into the premixed gas introduction portion occurs. Therefore, the communication portion can be appropriately configured by the communication space. And, in connecting the premixed gas pipe and the fuel gas pipe to the nozzle body, it is only necessary to connect the premixed gas introduction part and the fuel gas introduction part so as to form a communication space with a simple configuration. It is possible to simplify the configuration.

  A further characteristic configuration of the burner nozzle according to the present invention is that the premixed gas introduction part and the fuel gas introduction part have a larger diameter than the premixed gas introduction part, and the base end of the nozzle body. From the side, the fuel gas introduction part and the premixed gas introduction part are arranged adjacent to each other in order on the concentric shaft, and the premixed gas introduction part has a larger diameter or substantially the same as the premixed gas pipe. When the premixed gas pipe and the fuel gas pipe are connected to the nozzle body, a double pipe state in which the premixed gas pipe is on the inside and the fuel gas pipe is on the outside, The tip of the premixed gas pipe protrudes toward the tip of the nozzle body from the tip of the fuel gas pipe, and the protruding portion is spaced apart from the inner wall of the premixed gas introduction part. Enter the gas introduction section In writing state, there the fuel gas pipe to a point that is configured to be freely connected fitted into the fuel gas inlet.

  According to this feature configuration, the premixed gas pipe is connected to the fuel gas introducing portion by fitting the premixed gas pipe into the fuel gas introduction portion with the premixed gas pipe inside and the fuel gas pipe outside. Piping and fuel gas piping can be connected. In the connected state, the front end portion of the premixed gas pipe enters the premixed gas introduction section, so that the premixed gas is introduced into the premixed gas introduction section through the premixed gas pipe. And since the front-end | tip part of premixed gas piping is spaced apart from the inner wall part of a premixed gas introduction part, the adjacent fuel gas introduction part and premixed gas introduction part are connected by the clearance gap. Therefore, a communication space can be formed in the gap. Therefore, while adopting a simple connection configuration in which the fuel gas pipe is fitted and connected to the fuel gas introduction part, the protruding portion of the premix gas pipe is preliminarily spaced from the inner wall part of the premix gas introduction part. The communication space can be appropriately formed by a simple configuration of entering the mixed gas introduction section.

  In a further characteristic configuration of the burner nozzle according to the present invention, the premixed gas pipe is formed in a shape in which an outer peripheral portion of the protruding portion protruding from the tip of the fuel gas pipe is recessed radially inward. In the point.

  According to this characteristic configuration, the protruding portion of the premixed gas pipe is formed in a shape in which the outer peripheral portion is recessed radially inward, so that the space between the premixed gas introduction portion and the inner wall portion is reliably formed. be able to. Therefore, the formation of the communication space can be ensured.

  As a flame detection structure of a burner to which a burner nozzle according to the present invention is attached, it is preferable that a flame detection unit for detecting a flame formed by the gas ejected from the premixed gas ejection unit is provided.

  As described above, since the fuel gas ejecting portion is provided around the premixed gas ejecting portion, the gas ejected from the premixed gas ejecting portion is located in the center, and the gas from the fuel gas ejecting portion is disposed around the gas. Will be ejected. Thereby, as a position of the flame formed by the gas ejected from the premixed gas ejection section and the fuel gas ejection section, a flame is easily formed at a position where the gas from the premixed gas ejection section is ejected. Therefore, in this feature configuration, by providing a flame detection unit that detects a flame formed by the gas ejected from the premixed gas ejection unit, the gas ejected from the premixed gas ejection unit and the fuel gas ejection unit is provided. While detecting the flame formed in this manner with a simple configuration, the flame detection can be performed appropriately.

Diagram showing the overall structure of the burner Cross section of burner and burner nozzle The figure which shows the nozzle body in the axial direction view of the nozzle body Sectional view with the burner nozzle removed from the burner Sectional drawing of the burner nozzle in another embodiment Sectional drawing of the burner nozzle in another embodiment Cross-sectional view of a conventional burner and burner nozzle The figure which shows the nozzle main body in the axial direction view of the nozzle main body of a prior art example

An embodiment of a burner nozzle according to the present invention will be described based on the drawings.
The burner nozzle 1 is used in a burner 3 provided in a radiant tube 2 as shown in FIG. An attachment hole 6 for attaching the radiant tube 2 and the burner 3 is formed in the furnace wall 5 surrounding the furnace 4. The end of the radiant tube 2 is connected to the furnace wall 5 by fastening with a fastening member (for example, a bolt) or the like. It is attached to be exposed. The burner 3 has a base end portion (end portion on the X1 side in the drawing) connected to the furnace wall 5 by fastening with a fastening member (for example, a bolt) and is attached so as to be housed in the radiant tube 2. ing.

  As shown in FIGS. 1 to 3, the burner 3 is provided with a cylindrical combustion cylinder 7, and the combustion space 8 is divided into the space on the front end side of the combustion cylinder 7 and the internal space of the radiant tube 2 continuous therewith. It is said. The burner 3 burns by burning premixed gas G1, fuel gas G2, and combustion air A, which are a mixture of combustion air and fuel gas, into the combustion space 8 from a burner nozzle 1 attached to the tip of the burner 3. It is configured to let you. In addition to the burner nozzle 1, the burner 3 includes a premixed gas pipe 9 for introducing the premixed gas G1, a fuel gas pipe 10 for introducing the fuel gas G2, and a combustion air introducing portion 11 for introducing the combustion air A. It has.

  The premixed gas pipe 9 is formed in a cylindrical shape, and the premixed gas G1 supplied to the base end (end on the X1 side in the drawing) is supplied to the tip end (end on the X2 side in the drawing). It is comprised so that it may flow toward. The fuel gas pipe 10 is formed in a cylindrical shape having a diameter larger than that of the premixed gas pipe 9, and is configured to allow the fuel gas G2 supplied to the base end portion thereof to flow toward the tip end portion. Yes. The premixed gas pipe 9 and the fuel gas pipe 10 are provided in a double pipe state in which the premixed gas pipe 9 is on the inside and the fuel gas pipe 10 is on the outside, and the fuel gas G2 is a premixed gas. It is configured to flow between the outer wall portion of the pipe 9 and the inner wall portion of the fuel gas pipe 10. The combustion air introduction portion 11 is formed in a cylindrical shape having a diameter larger than that of the fuel gas pipe 10, and is connected to a proximal end portion of the combustion cylinder 7. The combustion air introduction part 11 covers the outer periphery of the fuel gas pipe 10, and introduces the combustion air A into the space between the fuel gas pipe 10 and the outer wall part.

  The burner nozzle 1 includes a nozzle body 12 formed in a cylindrical shape, and the nozzle body 12 is attached to the tip of the burner 3. As shown in FIGS. 2 and 4, the nozzle body 12 is provided with a circular premixed gas ejection portion 13 for ejecting the premixed gas G1 at the tip portion (the end portion on the X2 side in the drawing). A circular fuel gas ejection portion 14 that ejects the fuel gas G2 is provided on the proximal end side (the end portion on the X1 side in the drawing) of the nozzle body 12 with respect to the premixed gas ejection portion 13. Then, as viewed in the axial direction of the nozzle body 12, as shown in FIG. 3, the premixed gas ejection portion 13 is disposed at the center of the nozzle body 12, and in a circumferential direction surrounding the premixed gas ejection portion 13. In this embodiment, a plurality of fuel gas ejection portions 14 are provided at intervals, for example, eight fuel gas ejection portions 14 are spaced at regular intervals in the circumferential direction surrounding the periphery of the premixed gas ejection portion 13. Is provided. Thus, the premixed gas ejection part 13 and the fuel gas ejection part 14 are located close to each other in the radial direction of the nozzle body 12. In addition to the premixed gas G 1 and the fuel gas G 2, combustion air A is also supplied to the combustion space 8, and the combustion air A is discharged from the fuel gas ejection part 14 by the combustion air supply path 17. It is supplied from the surroundings.

  As shown in FIG. 2, the nozzle body 12 includes a premixed gas supply path 15 that supplies the premixed gas G <b> 1 introduced through the premixed gas pipe 9 to the premixed gas ejection section 13, and a fuel gas pipe 10. And a fuel gas supply path 16 for supplying the fuel gas G2 introduced in this way to the fuel gas ejection section 14. A combustion air supply passage 17 is provided around the nozzle body 12 to supply the combustion air A introduced into the combustion air introduction section 11 to the combustion space 8 separately from the premixed gas G1 and the fuel gas G2. Is provided. The combustion air supply path 17 has a base end side portion (X1 side portion in the figure) formed in a space between the outer wall portion of the fuel gas pipe 10 and the inner wall portion of the combustion cylinder 7. A tip side portion (X2 side portion in the figure) is formed in a space between the outer wall portion of the nozzle body 12 and the inner wall portion of the combustion cylinder 7. In the burner 3, the premixed gas G1 is passed through the center of the combustion cylinder 7, the fuel gas G2 is passed through the outer periphery of the premixed gas G1, and the combustion air A is placed around the outer periphery of the fuel gas G2. I let it flow. As described above, the burner 3 employs a triple-pipe structure in which the premixed gas pipe 9, the fuel gas pipe 10, and the combustion cylinder 7 are arranged in this order from the inner diameter of the combustion cylinder 7. Has been.

  As shown in FIGS. 2 and 4, the premixed gas supply path 15 is formed from the base end side (X1 side in the figure) of the nozzle main body 12, the premixed gas introduction portion 21, the first flow path portion 18, and the second flow. It arrange | positions so that it may arrange in order of the road part 19 adjacently. All of the premixed gas introduction part 21, the first flow path part 18, and the second flow path part 19 are formed in a cylindrical shape, and are provided so that their central axes are on concentric axes. The premixed gas introduction unit 21 is introduced with the premixed gas G1 through the premixed gas pipe 9 and has a larger diameter than the premixed gas pipe 9. The first flow path portion 18 is formed by a linear flow path extending from the proximal end side to the distal end side along the axial direction of the nozzle body 12, and the flow path diameter is formed to the same diameter over the entire length. Has been. The second flow path portion 19 is formed in a divergent shape in which the flow path diameter is larger toward the tip side of the nozzle body 12.

  The fuel gas supply path 16 is provided so that the fuel gas introduction part 20 and the third flow path part 22 are adjacently arranged in this order from the base end side (X1 side in the figure) of the nozzle body 12. The fuel gas introduction part 20 is formed in a cylindrical shape, and its central axis is the premixed gas introduction part 21, the first flow path part 18, and the second flow path part 19 in the premixed gas supply path 15. It is provided so that it may be on the concentric axis with the central axis. As a result, the fuel gas introduction part 20, the premixed gas introduction part 21, the first flow path part 18, and the second flow path part 19 are connected to the nozzle body 12 from the base end side (X1 side in the figure) of the nozzle body 12. Are arranged so as to be adjacent to each other in this order. A second screw portion 23 b that is screwed into a first screw portion 23 a formed on the outer wall portion of the fuel gas pipe 10 is formed on the inner wall portion of the fuel gas introduction portion 20. The second screw portion 23 b is formed over the entire length of the inner wall portion of the fuel gas introduction portion 20 in the axial direction of the nozzle body 12, and the entire fuel gas introduction portion 20 is a gas that connects the fuel gas pipe 10. It is configured as a pipe connection. The third flow path portion 22 extends from the periphery of the premixed gas introduction portion 21 to the outer side in the radial direction of the nozzle body 12, and is inclined so as to be positioned closer to the distal end side of the nozzle body 12 toward the outer side in the radial direction. It is formed in a shape.

  In connecting the premixed gas pipe 9 and the fuel gas pipe 10 to the nozzle body 12, as shown in FIG. 4, the premixed gas pipe 9 is inside and the fuel gas pipe 10 is outside. The second screw portion 23 b of the outer wall portion of the fuel gas pipe 10 is screwed into the first screw portion 23 a of the inner wall portion of the fuel gas introduction portion 20. In this way, the outer fuel gas pipe 10 of the premixed gas pipe 9 and the fuel gas pipe 10 in the double pipe state is fitted and connected to the fuel gas introduction portion 20, so that the nozzle body 12 is preliminarily connected. The mixed gas pipe 9 and the fuel gas pipe 10 are connected.

  In connecting the premixed gas pipe 9 and the fuel gas pipe 10 to the nozzle body 12, the leading end of the premixed gas pipe 9 protrudes from the leading end of the fuel gas pipe 10, and the protruding portion 25 is a premixed gas. It connects with the inner wall part of the introducing | transducing part 21 in the state which entered the premixed gas introducing | transducing part 21 at intervals. In this manner, the gap between the protruding portion 25 of the premixed gas pipe 9 and the inner wall portion of the premixed gas introduction portion 21 is separated, so that the gap between the premixed gas introduction portion 21 and the fuel gas introduction portion 20 is established. The premixed gas pipe 9 and the fuel gas pipe 10 are connected to the nozzle body 12 in a state where a communication space 24 is formed. The premixed gas introduction part 21 is formed to have a larger diameter than the premixed gas pipe 9, and the central axis of the premixed gas introduction part 21 and the central axis of the premixed gas pipe 9 are concentric, A space is formed between the outer wall portion of the projecting portion 25 in the premixed gas pipe 9 and the inner wall portion of the premixed gas introduction portion 21. And the communication space 24 which connects the premixed gas introduction part 21 and the fuel gas introduction part 20 is formed using this space | interval. In this embodiment, since the whole fuel gas introduction part 20 is configured as a gas pipe connection part, the inside of the fuel gas pipe 10 connected to the fuel gas introduction part 20 and the premixed gas introduction part 21 communicate with each other. Communicated through. Moreover, about the protrusion part 25 in the premixed gas piping 9, and the site | part connected to it, the outer peripheral part is formed in the shape hollowed in the radial inside. Thereby, a gap can be reliably formed between the outer wall portion of the projecting portion 25 in the premixed gas pipe 9 and the inner wall portion of the premixed gas introduction portion 21, and the communication space 24 can be appropriately formed. it can.

  In this way, by forming the communication space 24, gas mixing that mixes a part of the premixed gas G <b> 1 supplied in the premixed gas supply path 15 with the fuel gas supply path 16 through the communication space 24, and Then, at least one gas mixing with the gas mixing in which a part of the fuel gas G2 supplied in the fuel gas supply path 16 is mixed in the premixed gas supply path 15 occurs. Thus, the communication space 24 forms a communication portion K that communicates the midway portion of the premixed gas supply path 15 and the midway portion of the fuel gas supply path 16.

  In the premixed gas supply path 15, the first flow path portion 18 is provided with a swivel portion 29 for swirling and ejecting the premixed gas G <b> 1. The nozzle body 12 is provided with a spark rod 26 for igniting the premixed gas G1 ejected from the premixed gas ejection section 13. The spark rod 26 is provided in the premixed gas supply path 15, and is supported by the support portion 27 so as to penetrate the turning portion 29.

  As shown in FIG. 2, the burner 3 can supply both the premixed gas G <b> 1 and the fuel gas G <b> 2 to perform combustion in the combustion space 8. In this case, the premixed gas G1 is introduced into the premixed gas introduction section 21 of the premixed gas supply path 15 through the premixed gas piping 9 as shown by the thick line arrow in the figure, and the premixed gas supply is performed. The premixed gas ejection part 13 is supplied through the first flow path part 18 and the second flow path part 19 of the passage 15 and is ejected from the premixed gas ejection part 13. The fuel gas G2 is partly connected to the third flow path portion 22 of the fuel gas supply path 16 in the fuel gas pipe 10 connected to the entire fuel gas introduction section 20, as indicated by a thin line arrow in the figure. The remaining part is supplied to the premixed gas introduction part 21 through the communication space 24. Then, the fuel gas G <b> 2 supplied to the third flow path part 22 is supplied to the fuel gas ejection part 14 through the third flow path part 22 and is ejected from the fuel gas ejection part 14. On the other hand, the fuel gas G <b> 2 supplied to the premixed gas introduction unit 21 through the communication space 24 is mixed with the premixed gas G <b> 1 introduced into the premixed gas introduction unit 21 and ejected from the premixed gas ejection unit 13. ing.

  Although not shown, the burner 3 can stop the supply of the fuel gas G2 and supply only the premixed gas G1 to perform combustion in the combustion space 8. In this case, when the premixed gas G1 is introduced into the premixed gas introduction part 21 of the premixed gas supply path 15 in the premixed gas pipe 9, a part of the premixed gas G1 is supplied with the premixed gas supply. It is supplied to the premixed gas ejection part 13 through the first flow path part 18 and the second flow path part 19 of the path 15 and ejected from the premixed gas ejection part 13. Further, the remaining part of the premixed gas G1 flows into the fuel gas pipe 10 connected to the fuel gas inlet 20 from the premixed gas inlet 21 through the communication space 24, and the third of the fuel gas supply path 16. The fuel gas is ejected from the fuel gas ejection part 14 through the flow path part 22 and ejected from the fuel gas ejection part 14.

  Incidentally, when both the premixed gas G1 and the fuel gas G2 are supplied and combustion is performed in the combustion space 8, by adjusting the supply amount of the premixed gas G1 and the supply amount of the fuel gas G2, the combustion space is adjusted. The amount of combustion at 8 can be adjusted. In addition, when the fuel gas G2 is stopped and only the premixed gas G1 is supplied and combustion is performed in the combustion space 8, the supply amount of the premixed gas G1 is adjusted to adjust the supply amount of the premixed gas G1. The amount of combustion can be adjusted. Therefore, this burner 3 can take a large turndown ratio, and can also cope with a furnace used in a wide temperature range.

  As described above, in the burner nozzle 1, the premixed gas G1 and the fuel gas G2 are mixed by the communication portion K (communication space 24), and the mixed gas is fed from the premixed gas ejection portion 13 and the fuel gas ejection portion 14. Erupting. From this, the flame formed by the mixed gas can be considered as substantially one flame formed by the gas ejected from the premixed gas ejection portion 13 and the fuel gas ejection portion 14. Therefore, in this burner 3, as a flame detection unit for detecting a flame formed by the gas ejected from the premixed gas ejection unit 13, a viewing window for flame detection is provided at the proximal end of the premixed gas pipe 9. A portion 28 is provided. As a result, when the premixed gas G1 is introduced through the premixed gas pipe 9 and the fuel gas G2 is introduced through the fuel gas pipe 10 and combustion is performed, the premixing is performed by looking through the viewing window 28. A flame formed by a mixed gas in which the fuel gas G2 is mixed with the premixed gas G1 ejected from the gas ejection part 13 can be detected. Also, in the case where combustion is performed by stopping the introduction of the fuel gas G2 through the fuel gas pipe 10 and only the premixed gas G1 is introduced through the premixed gas pipe 9, it is possible to perform a pre- A flame formed by the premixed gas G1 ejected from the mixed gas ejection section 13 can be detected. As described above, the flame detection structure of the burner 3 is only required to include the observation window portion 28 as a flame detection portion, and the flame detection can be appropriately performed while the configuration can be simplified. .

[Another embodiment]
(1) In the above embodiment, the fuel gas ejection portion 14 is disposed on the proximal end side with respect to the premixed gas ejection portion 13 in the axial direction of the nozzle body 12, but as shown in FIGS. In the axial direction of the nozzle body, the fuel gas ejection part and the premixed gas ejection part can be arranged at the same position. Hereinafter, each of the burner nozzles shown in FIG. 5 and FIG. 6 will be described, but the description of the same configuration as in the above embodiment will be omitted by indicating the same reference numerals.

First, the burner nozzle shown in FIG. 5 will be described.
In FIG. 5, a premixed gas ejection portion 32 is disposed at the center of the nozzle body 31, and a fuel gas ejection portion 33 is provided so as to surround the premixed gas ejection portion 32. A premixed gas supply path 34 is arranged at the center of the nozzle body 31, and a fuel gas supply path 35 is provided so as to surround the premixed gas supply path 34. Both the premixed gas supply path 34 and the fuel gas supply path 35 are formed as linear flow paths having the same diameter extending along the axial direction of the nozzle body 31, and the premixed gas supply path 34 is the inside. The fuel gas supply path 35 is in a double tube state outside. A base end side portion of the premixed gas supply path 34 is used as a premixed gas introduction portion 36, and the premixed gas G <b> 1 is introduced into the premixed gas introduction portion 36 through a premixed gas pipe 37. The premixed gas pipe 37 is formed in a projecting shape having a distal end smaller in diameter than the base end side part, and the premixed gas introduction part 36 is formed in the same diameter as the base end side part of the premixed gas pipe 37. The tip of the premixed gas pipe 37 is formed to have a smaller diameter than the premixed gas introducing portion 36. The premixed gas pipe 37 is connected so that the protruding tip portion enters the premixed gas introducing portion 36 with a space between the premixed gas introducing portion 36 and the inner wall portion of the premixed gas introducing portion 36. Further, the base end side portion of the fuel gas supply path 35 is a fuel gas introduction part 38, and although not shown, the fuel gas pipe is connected so as to introduce the fuel gas G2 into the fuel gas introduction part 38. . For example, similarly to the above-described embodiment, it is possible to connect to the nozzle body 31 in a double tube state in which the premixed gas pipe 37 is on the inside and the fuel gas pipe is on the outside. In this way, the premixed gas pipe 37 and the fuel gas pipe are connected to the nozzle body 31 in a state where the communication space 39 that communicates between the premixed gas introduction section 36 and the fuel gas introduction section 38 is formed. Can do. By forming the communication space 39, a gas mixture for mixing a part of the premixed gas G1 supplied in the premixed gas supply path 34 with the fuel gas supply path 35 through the communication space 39, and a fuel gas supply path At least one gas mixing with the gas mixing in which a part of the fuel gas G2 supplied at 35 is mixed in the premixed gas supply path 34 occurs. As a result, the communication space K forms a communication portion K that communicates the intermediate portion of the premixed gas supply path 34 and the intermediate portion of the fuel gas supply path 35.

Next, the burner nozzle shown in FIG. 6 will be described.
In FIG. 6, unlike FIG. 5, the premixed gas pipe 37 is formed to have the same flow path diameter from the base end side portion to the tip end portion, and the premixed gas introduction portion 36 is connected to the premixed gas. It has a larger diameter than the pipe 37. The leading end of the premixed gas pipe 37 is connected so as to enter the premixed gas introducing portion 36 with a space between the tip portion and the inner wall portion of the premixed gas introducing portion 36. In this way, the premixed gas pipe 37 and the fuel gas pipe are connected to the nozzle body 31 in a state where the communication space 39 that communicates between the premixed gas introduction section 36 and the fuel gas introduction section 38 is formed. Can do. Also in FIG. 6, as in FIG. 5, by forming the communication space 39, a part of the premixed gas G <b> 1 supplied through the communication space 39 in the premixed gas supply path 34 is fuel gas. At least one gas mixture of the gas mixture mixed in the supply path 35 and the gas mixture mixed in the premixed gas supply path 34 with a part of the fuel gas G2 supplied in the fuel gas supply path 35 occurs. . As a result, the communication space K forms a communication portion K that communicates the intermediate portion of the premixed gas supply path 34 and the intermediate portion of the fuel gas supply path 35.

(2) In the above-described embodiment and the above-described (1), the premixed gas pipe and the fuel gas are formed with respect to the nozzle body in a state in which a communication space that communicates between the premixed gas introducing unit and the fuel gas introducing unit is formed. Pipes are connected. Instead of this, by forming a communication passage in the nozzle body that communicates the intermediate portion of the premixed gas supply passage and the intermediate portion of the fuel gas supply passage, the communication portion can be constituted by the communication passage. . In this case, the communication part K which connects the middle part of the premixed gas supply path and the middle part of the fuel gas supply path can be formed by the communication path. For example, as shown in FIGS. 5 and 6, in the case of a double pipe state in which the premixed gas supply path is the inner side and the fuel gas supply path is the outer side, the premixed gas supply path and the fuel gas supply path are in communication. The communication path to be formed can be formed on the tip side of the nozzle body from the premixed gas introduction part. In this case, the shape of the communication path is formed so as to be inclined so that the radially inner portion is located on the tip side of the nozzle body, or like the communication space 39 in FIGS. 5 and 6. In addition, it is possible to form a bent flow path in which the communication point with the premixed gas supply path is located closer to the tip of the nozzle body than the communication point with the fuel gas supply path.

(3) In the above embodiment, as a flame detection unit for detecting a flame formed by the gas ejected from the premixed gas ejection unit 13, a peek for flame detection is provided at the proximal end of the premixed gas pipe 9. A window 28 is provided. Instead of this, a flame detection sensor such as a frame rod may be arranged at a position where the gas from the premixed gas ejection portion 13 is ejected.

(4) In the above embodiment, the burner nozzle attached to the burner provided in the radiant tube is exemplified, but the present invention is not limited to such a burner, and can be applied to other burner nozzles attached to various burners.

  The present invention includes a premixed gas ejection portion that ejects a premixed gas in which combustion air and fuel gas are mixed, and a fuel gas ejection portion that ejects fuel gas around the premixed gas ejection portion. And various burner nozzles that can appropriately detect the flame while performing the flame detection formed by the gas ejected from the premixed gas ejection portion and the fuel gas ejection portion with a simple configuration, and the burner nozzle It can be applied to the flame detection structure of various burners equipped with

9 Premixed gas piping 10 Fuel gas piping 12 Nozzle body 13 Premixed gas ejection section 14 Fuel gas ejection section 15 Premixed gas supply path 16 Fuel gas supply path 20 Fuel gas introduction section 21 Premixed gas introduction section 24 Communication space 25 Projection Part 28 Flame detection part (view window part)
31 Nozzle body 32 Premixed gas ejection section 33 Fuel gas ejection section 34 Premixed gas supply path 35 Fuel gas supply path 36 Premixed gas introduction section 37 Premixed gas piping 38 Fuel gas introduction section 39 Communication space K Communication section

Claims (5)

  Introduced into the nozzle body is a premixed gas ejection section for ejecting a premixed gas in which combustion air and fuel gas are mixed, a fuel gas ejection section for ejecting fuel gas around the premixed gas ejection section, and A premixed gas supply path for supplying the premixed gas to be supplied to the premixed gas ejection section, a fuel gas supply path for supplying the introduced fuel gas to the fuel gas ejection section, and a middle of the premixed gas supply path The burner nozzle provided with the communication part which connects a site | part and the site | part in the middle of the said fuel gas supply path.   The premixed gas supply path includes a premixed gas introduction section through which a premixed gas is introduced through a premixed gas pipe, and the fuel gas supply path is a fuel into which fuel gas is introduced through a fuel gas pipe. The premixed gas pipe and the fuel gas pipe form a communication space that communicates between the premixed gas inlet and the fuel gas inlet with respect to the nozzle body. The burner nozzle according to claim 1, wherein the burner nozzle is configured to be freely connectable in a state, and the communication portion is formed in the communication space.   The premixed gas introducing section and the fuel gas introducing section are configured such that the fuel gas introducing section has a larger diameter than the premixed gas introducing section, and the fuel gas introducing section and the premixing section are arranged from the base end side of the nozzle body. The premixed gas introduction portion is formed to have a larger diameter or substantially the same diameter as that of the premixed gas pipe, and is arranged to be concentrically adjacent to each other in order of the gas introduction portion. In connecting the premixed gas pipe and the fuel gas pipe, the front end portion of the premixed gas pipe is the fuel gas pipe in a double pipe state in which the premixed gas pipe is inside and the fuel gas pipe is outside. The fuel gas pipe protrudes toward the tip of the nozzle body from the tip of the nozzle, and the protruding portion enters the premixed gas introduction part with a space between the inner wall part of the premixed gas introduction part. The fuel gas Burner nozzles according to claim 2, which is configured to be freely connected fitted into the join the club.   4. The burner nozzle according to claim 3, wherein the premixed gas pipe is formed in a shape in which an outer peripheral portion of the protruding portion protruding from a tip portion of the fuel gas pipe is recessed radially inward.   As a flame detection structure of a burner to which the burner nozzle according to any one of claims 1 to 4 is attached, a flame detection unit that detects a flame formed by gas ejected from the premixed gas ejection unit is provided. Burner flame detection structure.

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