JP2012255600A - Solid fuel burner and combustion device including the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To smooth the flow rate distribution and concentration distribution of fuel particles at a fuel nozzle outlet where a carrier gas and fuel particles flow even if gas with a low oxygen concentration is used for the carrier gas of a solid fuel, and to stably form flames immediately after the fuel nozzle outlet.SOLUTION: A solid fuel burner includes: a fuel nozzle which injects the mixture fluid of a solid fuel and a carrier gas; at least one combustion gas injection nozzle which is disposed outside the fuel nozzle and injects oxygen-containing gas; and at least two oxygen-containing gas addition nozzles which inject oxygen-containing gas having a velocity component in the circumferential direction of the fuel nozzle and are disposed to protrude in the fuel nozzle. An obstacle acting as a resistor against the flow of the mixture fluid flowing in the fuel nozzle is disposed downstream of the oxygen-containing gas addition nozzles in the fuel nozzle and between the oxygen-containing gas addition nozzles in the circumferential direction.

Description

  TECHNICAL FIELD The present invention relates to a solid fuel burner that burns air by conveying solid fuel and a combustion apparatus including the solid fuel burner, and particularly, a solid suitable for pulverizing fuel with a high water content and volatile content and carrying it by air flow for floating combustion. The present invention relates to a fuel burner and a combustion apparatus including the same.

  Fuels such as wood, fir and palm-derived biomass, and coals with low coalification such as peat, lignite, and lignite have many volatile components and contain a lot of moisture. It is known that it is easily ignited during storage, pulverization and transportation, and is difficult to handle compared to bituminous coal.

  When these fuels are pulverized and burned, in order to prevent spontaneous ignition, a mixed gas of combustion exhaust gas with a reduced oxygen concentration and oxygen-containing gas may be used as a fuel carrier gas. In particular, combustion exhaust gas lowers the oxygen concentration around the fuel, suppresses the oxidation reaction (combustion) of the fuel, and prevents spontaneous ignition. Further, the combustion exhaust gas has a function of drying moisture in the fuel by its retained heat.

  However, the combustion (oxidation) reaction of the fuel particles carried by the carrier gas having a low oxygen concentration is limited by the low oxygen concentration around the fuel particles when ejected from the solid fuel burner. For this reason, compared with the case where it conveys with air, a combustion speed is low, and it becomes more difficult to form a flame stably just after the exit of a solid fuel burner than it is conveyed with air.

  As a means for stably forming a flame while preventing spontaneous ignition as described above, it has been proposed to project an additional air nozzle for ejecting an oxygen-containing gas in a fuel nozzle of a solid fuel burner (Patent Document 1). reference).

  The solid fuel burner described in Patent Document 1 has an outlet of an additional air nozzle in the circumferential direction of the fuel nozzle, and jets oxygen-containing gas in the circumferential direction from the outlet, thereby near the outer peripheral partition wall of the fuel nozzle ( Hereinafter, a portion having a high oxygen concentration is formed on the outer peripheral portion of the fuel nozzle). According to the solid fuel burner described in Patent Document 1, since the surrounding oxygen concentration of the fuel particles increases at the outer peripheral portion of the fuel nozzle, the combustion (oxidation) reaction is accelerated, and a flame is formed from the vicinity of the fuel nozzle outlet. it can.

JP 2005-140480 A

  However, in the solid fuel burner described in Patent Document 1, an additional air nozzle for ejecting an oxygen-containing gas (hereinafter referred to as an additional nozzle) is provided so as to protrude into the fuel nozzle. The cross-sectional area of the fuel nozzle flow path is reduced, and the flow velocity of the mixed gas flowing through the fuel nozzle is increased in the reduced portion (hereinafter referred to as the reduced flow portion). For this reason, since the flow velocity once rises in the fuel nozzle, a difference in velocity distribution occurs in the circumferential direction in a portion downstream from the additional nozzle. That is, the downstream of the additional nozzle has a lower flow velocity than the average flow velocity obtained from the flow passage cross-sectional area and flow rate, and the downstream of the flow passage (constriction portion) sandwiched between the additional nozzles is higher than the average flow velocity.

  Furthermore, the fuel particles conveyed by the mixed gas have higher inertial force than the mixed gas. When the flow velocity of the fuel particles is increased in the contracted flow portion, the decrease in the flow velocity of the fuel particles is delayed from the mixed gas downstream thereof. For this reason, at the outlet of the fuel nozzle, the ejection speed of the fuel particles is higher than that of the mixed gas. In addition, the fuel particles gather in the contracted flow portion, and the concentration of the fuel particles decreases downstream of the additional nozzle.

  As a result, at the outlet of the fuel nozzle, the flow velocity of the fuel particles or the mixed fluid and the concentration of the fuel particles are not uniform in the circumferential direction. In the high flow rate part, the contact time with the hot gas staying in the circulating flow around the outlet of the fuel nozzle is shortened, and the contact with the circulating flow ends before the reaction of the fuel particles proceeds. It becomes easy to form. That is, it becomes difficult to form a flame stably immediately after the fuel nozzle outlet of the solid fuel burner.

  The present invention has been made in view of the above points, and its object is to provide a fuel nozzle outlet through which carrier gas and fuel particles flow even when a gas having a low oxygen concentration is used as a carrier gas for solid fuel. It is an object of the present invention to provide a solid fuel burner capable of smoothing the flow velocity distribution and the fuel particle concentration distribution and forming a flame stably immediately after the outlet of the fuel nozzle, and a combustion apparatus including the solid fuel burner.

  In order to achieve the above object, a solid fuel burner according to the present invention has a fuel nozzle that ejects a mixed fluid of solid fuel and its carrier gas, and at least one combustion that is disposed outside the fuel nozzle and ejects an oxygen-containing gas. An oxygen-containing gas jet nozzle, and an oxygen-containing gas having a velocity component in the circumferential direction of the fuel nozzle, and at least two oxygen-containing gas additional nozzles provided so as to protrude into the fuel nozzle. In at least one of the gas addition nozzles, a solid fuel burner having a nozzle outlet in a circumferential direction of the fuel nozzle, the oxygen-containing gas addition nozzle in the fuel nozzle downstream of the oxygen-containing gas addition nozzle An obstacle serving as a resistance against the flow of the mixed fluid flowing through the fuel nozzle is provided between the circumferential directions of the gas addition nozzles.

  In order to achieve the above object, the combustion apparatus of the present invention includes a furnace including a plurality of solid fuel burners having the above-described configuration, a fuel hopper, a coal feeder, and a combustion exhaust gas downstream of the coal feeder. A pulverizer that introduces fuel mixed with combustion exhaust gas extracted from the upper part of the combustion device in the pipe, a fuel pipe that supplies the fuel crushed by the pulverizer to the solid fuel burner, and air to the solid fuel burner. And a blower to be supplied.

  According to the present invention, even if a gas having a low oxygen concentration is used as the carrier gas for the solid fuel, the flow velocity distribution at the outlet of the fuel nozzle through which the carrier gas or fuel particles flow and the concentration distribution of the fuel particles are smoothed. A flame can be stably formed immediately after the nozzle outlet.

FIG. 2 is a cross-sectional view showing the structure of the first embodiment of the solid fuel burner according to the present invention, in which the flame of the solid fuel burner is formed from the vicinity of the circulation flow downstream of the flame holder. It is a figure which shows the schematic structure which looked at the solid fuel burner of Example 1 from the furnace side. It is a schematic diagram explaining the structure of the oxygen-containing gas nozzle and obstacle of the solid fuel burner of Example 1, and the fuel jet in the fuel nozzle, that is, the flow of fuel and its carrier gas. It is a schematic diagram explaining the modification of Example 1 of the solid fuel burner by this invention. It is a schematic diagram explaining another modification of Example 1 of the solid fuel burner by this invention. It is a structure of Example 2 of the solid fuel burner by this invention, and is sectional drawing which shows the state which formed the flame of the solid fuel burner from near the circulation flow of the downstream of a flame holder. It is a structure of Example 3 of the solid fuel burner by this invention, and is sectional drawing which shows the state which formed the flame of the solid fuel burner from near the circulation flow of the downstream of a flame holder. It is a figure which shows the schematic structure which looked at the solid fuel burner of Example 3 from the furnace side. It is a figure which shows schematic structure of the combustion apparatus using the solid fuel burner by this invention.

  The solid fuel burner of the present invention will be described below based on the illustrated embodiment.

  1 and 2 show Embodiment 1 of the solid fuel burner of the present invention. As shown in the figure, the solid fuel burner includes an oil gun 5 at the center, and a fuel nozzle 1 through which fuel particles and a carrier gas (hereinafter referred to as a mixed fluid) 11 flow. Outside the outer peripheral partition wall 4 of the fuel nozzle 1, there are a secondary nozzle 2 and a tertiary nozzle 3 that are combustion gas ejection nozzles for ejecting combustion gases 12 and 13 into the furnace 10. Is connected to a furnace wall 6 having a heat transfer tube 7 on the furnace 10 side.

  Further, the secondary nozzle 2 and the tertiary nozzle 3 are provided with dampers 8 and 9 for adjusting the flow rate and a swirler 14 for inducing a speed component in the circumferential direction with respect to the flow of the fuel nozzle 1 on the upstream side. Yes. The upstream side of the secondary nozzle 2 and the tertiary nozzle 3 is connected to the wind box 15. The oil gun 5 described above is used to increase the temperature in the furnace 10 and promote ignition of the fuel particles when the solid fuel burner is started.

  The tip of the outer peripheral partition wall 4 of the fuel nozzle 1, that is, the outlet side of the furnace 10, is between the mixed fluid flow 11 ejected from the fuel nozzle 1 and the combustion gas flow 12 ejected from the secondary nozzle 2, and the pressure Decreases. Since this portion has a low pressure, a flow in a direction opposite to that of the mixed fluid flow 11 and the combustion gas flow 12 is induced. This reverse flow is called a circulating flow 16.

  In the circulating flow 16, hot gas generated by fuel combustion flows from the downstream and stays there. The high temperature gas and the fuel particles in the flow 11 of the mixed fluid are mixed at the outlet of the solid fuel burner, and further, the temperature of the fuel particles rises due to the radiant heat from the inside of the furnace 10 and ignites.

  The secondary nozzle 2 and the tertiary nozzle 3 are separated by a partition wall 17, and the tip portion of the partition wall 17 is a combustion gas ejected from the outlet of the tertiary nozzle 3 with respect to the mixed fluid flow 11 flowing through the fuel nozzle 1. A guide 18 is formed to eject the flow 13 so as to have an angle.

  As described above, when the guide 18 that guides the ejection direction of the combustion gas in the direction away from the burner central axis is provided at the outlet of the nozzle (for example, the secondary nozzle 2 or the tertiary nozzle 3) that ejects the combustion gas, circulation occurs. Helps to form stream 16.

  In the solid fuel burner of the present embodiment, a gas having a lower oxygen concentration than air is often used as the fuel carrier gas. An example of such a carrier gas is a mixed gas of combustion exhaust gas and air. By making the oxygen concentration lower than that of air, the oxygen concentration around the fuel is lowered, the oxidation reaction (combustion) of the fuel is suppressed, and the fuel nozzle 1 and the upstream pipe connected to the fuel nozzle 1 or inside the pulverizer Can prevent spontaneous ignition. Further, by using high-temperature combustion exhaust gas, it is possible to dry the moisture in the fuel by the retained heat.

  Examples of the fuel suitable for fuel transportation at such a low oxygen concentration include biomass derived from plants such as wood, fir and cocoon, and coal having a low degree of coalification such as peat, lignite and lignite.

  Thus, in order to promote the ignition of the fuel particles transported by the fuel transport gas having a low oxygen concentration, the additional nozzle 20 for ejecting the oxygen-containing gas is installed in the fuel nozzle 1 so as to protrude into the fuel nozzle 1. ing. The additional nozzle 20 has a shape that is gradually reduced and enlarged so that the flow passage cross-sectional area in the fuel nozzle 1 is smoothly reduced and enlarged. A portion of the oxygen-containing gas ejection hole 21 is provided on the side surface of the additional nozzle 20 (in the circumferential direction of the fuel nozzle 1).

  In the solid fuel burner of this embodiment shown in FIG. 1, the additional nozzle 20 is connected to the wind box 15 via a damper 22 for adjusting the flow rate, and the combustion gas is ejected from the ejection hole 21 as an oxygen-containing gas. . In addition, it is also possible to introduce | transduce oxygen-containing gas separately from the outer side of a solid fuel burner irrespective of the structure of FIG.

  By jetting oxygen-containing gas in the circumferential direction with respect to the flow 11 of the mixed fluid flowing through the fuel nozzle 1 from the additional nozzle 20, near the outer peripheral partition wall 4 of the fuel nozzle 1 (hereinafter referred to as the fuel nozzle outer peripheral portion), A portion having a high oxygen concentration is formed. For this reason, since the surrounding oxygen concentration of the fuel particles increases at the outer periphery of the fuel nozzle, the combustion (oxidation) reaction is accelerated, and the flame 24 can be formed from the vicinity of the outlet of the fuel nozzle 1.

  In the first embodiment, the obstacle 30 is a resistor against the flow of the mixed fluid flowing through the fuel nozzle 1 on the downstream side of the additional nozzle 20 in the fuel nozzle 1 and between the circumferential directions of the additional nozzle 20. Is provided. Hereinafter, the obstacle 30 will be described with reference to FIGS. 1 to 3. In FIG. 3, the outer peripheral side partition 4 of the fuel nozzle 1 is omitted.

  As shown in the figure, the obstacle 30 is installed downstream of the additional nozzle 20 installed near the outer peripheral partition 4 of the fuel nozzle 1 and between the circumferential directions of the additional nozzle 20, as shown in FIG. In addition, the additional nozzle 20 adjacent in the circumferential direction is located downstream of the contracted portion 31 where the flow path cross-sectional area of the fuel nozzle 1 is narrowed.

  The velocity of the flow 11 of the mixed fluid flowing through the fuel nozzle 1 is accelerated at the contracted portion 31 where the flow passage cross-sectional area of the fuel nozzle 1 is narrowed. On the downstream side of the contracted portion 31, the flow path cross-sectional area increases smoothly, and the oxygen-containing gas flow 23 ejected from the ejection holes 21 of the additional nozzle 20 mixes with the mixed fluid flow 11. The flow velocity of the mixed fluid flow 11 accelerated by the contracted flow portion 31 decreases as the flow path cross-sectional area increases. It becomes. That is, the flow velocity is high downstream of the contracted flow portion 31, and the flow velocity is low downstream of the additional nozzle 20. In particular, the solid fuel particles in the mixed fluid stream 11 have a higher specific gravity than the gas component and a strong inertial force, so the non-uniformity in the flow velocity is large. Further, the concentration of solid fuel particles (hereinafter referred to as fuel concentration) is high downstream of the contracted flow portion 31, and the concentration of solid fuel particles tends to be low downstream of the additional nozzle 20.

  When the fuel concentration distribution and the flow velocity distribution are not uniform, the flame propagation between the fuel particles is delayed in the portion where the fuel concentration is low. Moreover, the contact time with the hot gas which stays in the circulation flow of the outer periphery of a fuel nozzle exit becomes short in the part with a high flow velocity. For this reason, the reaction of the fuel particles is difficult to proceed, and the flame 24 is easily formed away from the fuel nozzle 1. That is, it becomes difficult to form the flame 24 stably immediately after the fuel nozzle exit of the solid fuel burner.

  On the other hand, when the obstacle 30 is provided on the downstream side of the constricted flow portion 31 where the flow passage cross-sectional area of the fuel nozzle 1 is narrowed, the flow resistance of the mixed fluid 11 is likely to spread in the circumferential direction because the obstacle 30 increases the flow resistance. . For this reason, the non-uniformity in the circumferential direction of the fuel concentration distribution and the flow velocity distribution is reduced at the outlet outer peripheral portion of the fuel nozzle 1. That is, since the portion with low fuel concentration and the portion with high flow velocity are reduced, the reaction of the fuel particles proceeds, and the flame 24 can be stably formed immediately after the fuel nozzle 1.

  By adopting such a configuration of the first embodiment, the mixed fluid flow 11 passes through the contracted portion 31 of the fuel nozzle 1 formed by the additional nozzle 20, and then a part of the mixed fluid flow 11 is caused by the obstacle 30 in the circumferential direction. Since the fuel particles and the fluid mixture are dispersed in the circumferential direction, the flow velocity difference in the circumferential direction and the concentration difference of the fuel particles are reduced and smoothed at the fuel nozzle outlet. For this reason, the portion where the flow velocity is high is reduced, the contact time with the high temperature gas staying in the circulation flow around the outlet of the fuel nozzle is long, and the contact time with the circulation flow is long. It is formed at a position close to the fuel nozzle 1. That is, a flame is stably formed immediately after the fuel nozzle outlet of the solid fuel burner, and stable combustion is facilitated.

  Therefore, even if a gas having a low oxygen concentration is used as the carrier gas for the solid fuel, the flow velocity distribution and the fuel particle concentration distribution at the fuel nozzle outlet through which the carrier gas and fuel particles flow are smoothed and immediately after the fuel nozzle outlet. Can form a flame stably.

  In addition to the cylindrical shape as shown in FIG. 3, the shape of the obstacle 30 can be smoothly flown by gradually expanding from the downstream side and gradually reducing from the middle as shown in FIG. 4. As shown in FIG. 5, a rhombus shape whose cross-sectional area is changed, or a shape in which the cross-sectional area of the flow path is smoothly changed on the downstream side by gradually reducing the upstream side toward the downstream side as shown in FIG.

  As shown in FIG. 4 or FIG. 5, the flow passage cross-sectional area is smoothly changed on the downstream side, so that a portion with a low flow velocity of the mixed fluid flow 11 is hardly formed downstream of the obstacle 30. For this reason, the flow velocity distribution at the outlet of the fuel nozzle 1 becomes uniform. In addition, fuel particles are difficult to deposit in the portion of the fuel nozzle 1 where the flow velocity is low.

  Furthermore, as shown in FIG. 3 and FIG. 5, the upstream side has a cylindrical shape, so that when the fuel particles collide, they are easily dispersed in the circumferential direction. Further, when the upstream side is a flat surface as shown in FIG. 4, the collision angle with respect to the flow of the fuel particles is in a certain range, so that it is easy to suppress wear. In addition, since fuel particles collide with the upstream side of the obstacle 30, it is desirable to use a wear resistant material such as ceramic. Further, since the downstream side of the obstacle 30 is susceptible to radiant heat from inside the furnace 10, it is desirable to use a heat-resistant material made of a heat-resistant metal such as stainless steel.

  FIG. 6 shows a second embodiment of the solid fuel burner of the present invention. The difference between the second embodiment shown in FIG. 6 and the first embodiment shown in FIG. 1 is the following three points, and the other configurations are substantially the same as those of the first embodiment.

  1) Inside the fuel nozzle 1, on the upstream side of the additional nozzle 20, a venturi 40 having a shape that reduces and expands the cross-sectional area of the fuel nozzle 1 from the outside, and reduces the cross-sectional area of the fuel nozzle 1 from the inside. Having a concentrator 41 that expands.

  2) At the downstream end of the outer peripheral partition 4 of the fuel nozzle 1, a flame holder 19 that obstructs the flow 11 of the mixed fluid ejected from the fuel nozzle 1 and the flow 12 of the combustion gas ejected from the secondary nozzle 2. Having

  3) A distributor 42 that divides the flow path of the fuel nozzle 1 into an inner peripheral side and an outer peripheral side, respectively, is provided in a portion of the fuel nozzle 1 where the additional nozzle 20 is located, and the fuel nozzle divided by the distributor The additional nozzle and the obstacle are positioned in the flow path.

  The difference 1 is a configuration in which fuel particles are concentrated near the inner peripheral partition 4 of the fuel nozzle 1.

  The venturi 40 has a shape that smoothly reduces and expands the cross-sectional area of the fuel nozzle 1 from the outer peripheral side, and the concentrator 41 has a shape that smoothly reduces and expands the cross-sectional area of the fuel nozzle 1 from the inside. have. The fuel particles in the mixed fluid stream 11 have a higher inertial force than the carrier gas. For this reason, in the part where a flow-path cross-sectional area expands, while carrier gas expands rapidly, a fuel particle shows the tendency to remain as it is.

  The fuel particles stay in the vicinity of the outer peripheral partition 4 on the outer peripheral side of the fuel nozzle 1 on the downstream side of the venturi 40 and further on the downstream side of the concentrator 41, and the fuel particles are concentrated on the outer peripheral side. At the outlet portion of the nozzle 1, the concentration of fuel particles near the circulating flow 16 at the outlet of the fuel nozzle 1 increases. With high concentration of fuel particles, flame propagation proceeds, and it becomes easy to stably form the flame 24 immediately after the outlet of the fuel nozzle 1 of the solid fuel burner.

  The difference 2 is about the structure which expands the circulating flow 16 formed downstream of the outer peripheral side partition 4 of the fuel nozzle 1.

  If a flame stabilizer 19 that changes the direction of the mixed fluid flow 11 and the combustion gas flow 12 flowing at the side is used at the tip of the outer peripheral partition 4 of the fuel nozzle 1, the downstream portion of the outer peripheral partition 4 is , Ie, the mixed fluid stream 11 and the combustion gas stream 12 are separated, so that the pressure is reduced. For this reason, the area of the circulating flow 16 is enlarged. High-temperature gas stays in the circulating flow 16. As the reaction of the fuel particles progresses and the downstream gas, which has reached a high temperature, flows through the circulating flow 16 and returns to the vicinity of the solid fuel burner, the temperature of the gas staying in the circulating flow 16 rises. Since this high-temperature gas is mixed with the fuel particles ejected from the fuel nozzle 1, the combustion reaction is accelerated, so that the flame propagation of the fuel particles proceeds, and the flame 24 is stably formed immediately after the outlet of the fuel nozzle 1 of the solid fuel burner. It becomes easy to do.

  The difference 3 is a configuration of a portion closely related to the obstacle 30 as an object of the present invention.

  The distributor 42 divides the flow path of the fuel nozzle 1 into an inner peripheral flow path 43 and an outer peripheral flow path 44. Among these, the flow path 44 on the outer peripheral side is close to the circulating flow 16 on the downstream side. In particular, the distributor 42 has an additional air nozzle 20 when viewed from the direction perpendicular to the oil gun 5 in the fuel nozzle 1 which is a burner shaft as shown in FIG. 6 (YY ′ direction in FIG. 6). It is desirable to provide in the position where the ejection hole 21 which is the exit of this and the obstacle 30 overlap. At this time, the ejection hole 21 and the obstacle 30 of the additional nozzle 20 are located in the flow path 44 on the outer peripheral side.

  The oxygen concentration of the mixed fluid is increased in the outer peripheral flow path 44 by the oxygen-containing gas ejected from the additional nozzle 20. At this time, since the flow path is divided by the distributor 42, the oxygen-containing gas is less diffused and the oxygen concentration is increased than when the distributor 42 is not provided. Further, even when the obstruction 30 causes disturbance in the flow 11 of the mixed fluid, oxygen and fuel particles do not diffuse to the inner peripheral side, so that the oxygen concentration and the fuel concentration can be kept high.

  According to the second embodiment, the same effect as that of the first embodiment can be obtained. According to the second embodiment, the mixed fluid can reach the fuel nozzle outlet while the oxygen concentration and the fuel concentration remain high. Therefore, when mixing with the circulating flow 16, the flame propagation of the fuel particles proceeds due to the high oxygen concentration and the fuel concentration, and the flame 24 is stably delivered immediately after the fuel nozzle outlet of the solid fuel burner. It becomes easy to form.

  7 and 8 show a third embodiment of the solid fuel burner of the present invention, which is an example employing a toothed flame holder.

  As shown in the figure, in Example 3, the flow of the solid fuel ejected from the fuel nozzle 1 and its carrier gas and the mixture ejected from the additional nozzle 20 are disposed at the downstream end of the outer peripheral partition 4 which is the outlet of the fuel nozzle 1. A toothed flame holder 19 with a plate-like edge 50 that obstructs the gas flow 11 is provided.

  As a result, the same effects as in the first embodiment can be obtained, and according to the third embodiment, the mixed fluid diffuses on the downstream side of the outlet of the fuel nozzle 1 and mixes with the circulating flow 16 existing on the outer periphery thereof. At this time, since the flame stabilizer 19 is installed at the edge 50, the high temperature gas flowing through the circulating flow 16 and the mixed fluid are mixed, and the temperature around the fuel particles is increased. As the flame propagation of the particles progresses, it becomes easy to stably form the flame 24 immediately after the fuel nozzle outlet of the solid fuel burner.

  In order to stably form the flame 24, the edge 50 preferably has a shape that suddenly changes the flow path cross-sectional area having a plane perpendicular to the flow. By changing the cross-sectional area abruptly, it becomes easy to form a low flow velocity portion or a circulating flow having a low pressure on the downstream side.

  On the other hand, the obstacle 30 provided in the fuel nozzle 1 is provided with the outer peripheral partition 4 on the downstream side thereof, so that the flow 11 of the mixed fluid cannot be diffused in the radial direction of the fuel nozzle 1. For this reason, it is mainly diffused in the circumferential direction, and the non-uniformity in the circumferential direction of the fuel concentration distribution and the flow velocity distribution is reduced in the outer peripheral portion of the outlet of the fuel nozzle 1. desirable. Further, the downstream side of the obstacle 30 preferably has a shape that smoothly changes the channel cross-sectional area. By smoothly changing the flow path, it becomes difficult to form a low flow rate portion with low pressure or a circulating flow. For this reason, since it becomes difficult for fuel particles to accumulate in the fuel nozzle 1, the downstream side of the obstacle 30 preferably has a shape that smoothly changes the flow path cross-sectional area. By smoothly changing the flow path, it becomes difficult to form a low flow rate portion with low pressure or a circulating flow.

FIG. 9 shows a combustion apparatus using the solid fuel burner of the present invention. In the fourth embodiment shown in the figure, the combustion apparatus (furnace) 51 has two stages in the vertical direction, and any one of the first to third embodiments. The solid fuel burner 52 described in the above is installed. The fuel is supplied from the fuel hopper 53 to the pulverizer 55 through the coal feeder 54, pulverized by the pulverizer 55, and then supplied to the solid fuel burner 52 through the fuel pipe 57. At this time, part of the combustion exhaust gas extracted from the exhaust port 60 at the top of the furnace 51 is mixed with fuel in the combustion exhaust gas pipe 56 on the downstream side of the coal feeder 54 and introduced into the pulverizer 55.

  When the fuel is mixed with the high-temperature combustion gas, moisture contained in the fuel evaporates. Further, since the oxygen concentration is reduced, spontaneous ignition and explosion can be suppressed even if the pulverizer 55 is pulverized to have a high temperature. In the case of lignite, the oxygen concentration of the carrier gas is often about 6 to 15%. Air is supplied from the blower 58 to the solid fuel burner 52 and an after air port 59 provided downstream thereof.

  In the present embodiment, a two-stage combustion method is used in which less air than the amount of air necessary for complete combustion of fuel is supplied from the solid fuel burner 52 and the remaining air is supplied from the after air port 59.

  The combustion apparatus using the solid fuel burner of the present invention can also be applied to a single-stage combustion system in which all necessary air is supplied from the solid fuel burner 52 without providing the after air port 59. Further, the installation position of the solid fuel burner 52 can be provided on one side wall or a corner portion, as well as on the front and rear walls as shown in FIG.

  Further, FIG. 9 shows a case where there is no temporary fuel storage part between the pulverizer 55 and the solid fuel burner 52, but it is also possible to have a fuel storage part after pulverization. Further, it is possible to have a plurality of fuel hoppers 53 and switch the fuel hopper 53 to be used according to the situation.

  By using the solid fuel burner 52 described in the first to third embodiments as the solid fuel burner 52, even when the oxygen concentration of the fuel carrier gas is low, the outer peripheral portion of the outlet of the fuel nozzle 1 has a periphery of the fuel concentration distribution and the flow velocity distribution. Directional non-uniformity is reduced. That is, since the portion with low fuel concentration and the portion with high flow velocity are reduced, the reaction of the fuel particles proceeds, and the flame 24 can be stably formed immediately after the fuel nozzle 1.

  DESCRIPTION OF SYMBOLS 1 ... Fuel nozzle, 2 ... Secondary nozzle, 3 ... Tertiary nozzle, 4, 17 ... Outer partition wall, 5 ... Oil gun, 6 ... Furnace wall, 7 ... Heat transfer tube, 8, 9, 22 ... Damper, 10, 51 ... furnace, 11 ... mixed fluid flow, 12, 13 ... combustion gas flow, 14 ... swirler, 15 ... wind box, 16 ... circulating flow, 18 ... guide, 19 ... flame holder, 20 ... additional nozzle , 21 ... ejection hole, 23 ... flow of oxygen-containing gas, 24 ... flame, 30 ... obstruction, 31 ... constricted part, 40 ... venturi, 41 ... concentrator, 42 ... distributor, 43, 44 ... flow path, DESCRIPTION OF SYMBOLS 50 ... Edge, 52 ... Solid fuel burner, 53 ... Fuel hopper, 54 ... Coal feeder, 55 ... Crusher, 56 ... Fuel exhaust gas piping, 57 ... Fuel piping, 58 ... Blower, 59 ... After air port, 60 ... Discharge port .

Claims (10)

A fuel nozzle that ejects a mixed fluid of the solid fuel and its carrier gas, at least one combustion gas ejection nozzle that is disposed outside the fuel nozzle and ejects an oxygen-containing gas, and a circumferential velocity component of the fuel nozzle. An oxygen-containing gas having at least two oxygen-containing gas addition nozzles provided to protrude into the fuel nozzle, and at least one of the oxygen-containing gas addition nozzles includes a circumferential direction of the fuel nozzle. In a solid fuel burner having a nozzle outlet at
An obstacle serving as a resistance against the flow of the mixed fluid flowing through the fuel nozzle is provided downstream of the oxygen-containing gas additional nozzle in the fuel nozzle and between the circumferential directions of the oxygen-containing gas additional nozzle. A solid fuel burner characterized by that. The solid fuel burner according to claim 1,
The solid fuel burner according to claim 1, wherein the obstacle is provided on a downstream side of a portion where a flow passage cross-sectional area of the fuel nozzle is narrowed by at least two oxygen-containing gas addition nozzles. The solid fuel burner according to claim 1 or 2,
A distributor for dividing the flow path of the fuel nozzle into an inner peripheral side and an outer peripheral side is arranged in a portion where the oxygen-containing gas additional nozzle in the fuel nozzle is located at least, and the fuel nozzle divided by the distributor A solid fuel burner characterized in that the oxygen-containing gas addition nozzle and the obstacle are located in the flow path. The solid fuel burner according to claim 3.
The distributor is provided at a position where it overlaps the obstacle and the nozzle outlet of the oxygen-containing gas additional nozzle when viewed from the vertical direction with respect to the oil gun located in the center of the fuel nozzle. Solid fuel burner characterized by The solid combustion burner according to any one of claims 1 to 4,
In the fuel nozzle on the upstream side of the oxygen-containing gas addition nozzle, a venturi having a shape that smoothly reduces and expands the cross-sectional area of the fuel nozzle from the outer peripheral side, and the cross-sectional area of the fuel nozzle from the inside A solid fuel burner comprising a concentrator having a shape that smoothly contracts and expands. The solid fuel burner according to any one of claims 1 to 5,
A solid fuel burner characterized in that a flame holder that prevents at least the flow of oxygen-containing gas ejected from the oxygen-containing gas additional nozzle is installed at the tip of an outer peripheral partition that is an outlet of the fuel nozzle. The solid fuel burner according to claim 6.
The solid fuel burner according to claim 1, wherein the flame holder is a toothed flame holder having an edge protruding from an outlet of the fuel nozzle. The solid fuel burner according to any one of claims 1 to 7,
The obstacle is a solid fuel characterized in that the cross-section is a cylinder, or a rhombus whose flow path cross-sectional area is smoothly changed on the downstream side, or a cylinder whose upstream side is cylindrical and whose flow cross-sectional area is smoothly changed on the downstream side. Burner. The solid fuel burner according to claim 8,
A solid fuel burner characterized in that the obstacle is formed of a wear resistant material on the upstream side and a heat resistant material on the downstream side.   A furnace equipped with a plurality of the solid fuel burners according to any one of claims 1 to 9, a fuel hopper, a coal feeder, and a combustion exhaust gas pipe on the downstream side of the coal feeder, extracted from the upper part of the combustion device A pulverizer for introducing the fuel mixed with the combustion exhaust gas, a fuel pipe for supplying the pulverized fuel to the solid fuel burner, and a blower for supplying air to the solid fuel burner. Combustion device characterized by.

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