JP3924089B2 - Pulverized coal burner and combustion apparatus using pulverized coal burner - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
TECHNICAL FIELD The present invention relates to a pulverized coal burner that conveys coal and burns it, and more particularly to a pulverized coal burner that is effective in reducing nitrogen oxide concentration, and a combustion apparatus that uses this pulverized coal burner.
[0002]
[Prior art]
Most of the NOx (nitrogen oxides) generated during the combustion of pulverized coal is so-called fuel NOx, which is generated by oxidizing the nitrogen contained in the coal. HCN (hydrogen cyanide) or NH during the reaction _Three Released as (ammonia) into the gas phase.
By the way, these nitrogen compounds are oxidized to NOx under high oxygen concentration conditions, but are reduced and harmless N when oxygen concentration is low. ₂ (Nitrogen).
[0003]
Currently, various pulverized coal combustion methods are being studied in order to reduce NOx generated from coal-fired boilers and coal combustion furnaces. As a typical combustion method, an air-deficient region is formed in the flame. HCN and NH released from coal in the region _Three There is a method of utilizing the reduction reaction of NOx by
[0004]
In this method, fuel is burned in the burner section in a state where air is insufficient, and then air for complete combustion is injected in the wake of the flame to burn the remaining combustible components. As a burner according to the method, for example, there is one disclosed in Japanese Patent Application Laid-Open No. 62-276310, which supplies combustion air divided into primary, secondary and tertiary, and further uses tertiary air as swirling flow. In addition, the NOx reduction region is expanded by delaying mixing with the coal in the center of the flame.
[0005]
Here, in order to suppress NOx generated by pulverized coal combustion, it is necessary to accelerate ignition of pulverized coal, promote consumption of oxygen, and expand the NOx reduction region formed in the flame. As a method for accelerating the ignition, there are methods described in, for example, Japanese Patent Laid-Open Nos. 8-200268, 2-53688, or 9-159109.
[0006]
In these methods, a swirling flow generator and a flow path reduction and expansion part are provided in the pulverized coal nozzle, utilizing the difference in inertia force between the pulverized coal and air, and collecting the pulverized coal on the outer periphery of the nozzle by centrifugal force, As a result, the ignition of pulverized coal is accelerated.
[0007]
First, the prior art described in the above-mentioned Japanese Patent Application Laid-Open No. 2-53688 will be described with reference to FIGS. 13 and 14. Here, FIG. 13 is a side including the central axis (shown by a broken line) of the pulverized coal burner. FIG. 14 is a cross-sectional view, and FIG. 14 is a front view of the pulverized coal burner nozzle as viewed along the central axis, and corresponds to a view seen from the direction of arrow X in FIG.
[0008]
In these drawings, reference numeral 11 denotes a pulverized coal nozzle attached to the center of the burner, and a secondary nozzle 12 and a tertiary nozzle 13 which are sequentially arranged concentrically on the outside of the pulverized coal nozzle 11 are provided.
First, the pulverized coal nozzle 11 is formed as a tubular flow path having the primary throat 14 as an outer peripheral wall, and the secondary nozzle 12 has the primary throat 14 as an inner peripheral wall and the secondary throat 15 as an outer peripheral wall. Further, the tertiary nozzle 14 is an annular flow path having the secondary throat 15 as an inner peripheral wall and the tertiary throat 16 as an outer peripheral wall.
Here, the pulverized coal nozzle 11 serves to eject primary air 17 composed of a mixed flow of carrier air and coal particles (pulverized coal), and the secondary nozzle 12 and the tertiary nozzle 13 are respectively a secondary air 18, It functions to eject the tertiary air 19 and, in this way, by arranging the three types of nozzles concentrically with the primary, secondary, and tertiary nozzles, the object of flow is improved.
[0009]
In this conventional example, an oil gun 20 is provided through the pulverized coal nozzle 11, and fuel oil such as heavy oil is supplied to the oil gun 20, thereby facilitating the start of combustion when the burner is activated and low-load combustion. Sometimes fuel oil is supplied to maintain combustion.
[0010]
The pulverized coal nozzle 11 is connected to a pulverized coal transport pipe (not shown) on the upstream side, whereby primary air 17 consisting of a mixed flow of pulverized coal and transport air is supplied, and at the same time, air (not shown) Pressure air is introduced from the blower to the wind box 21, becomes secondary air 18 and tertiary air 19, is supplied to the secondary nozzle 12 and the tertiary nozzle 13, and is ejected from the respective nozzles.
[0011]
At this time, a swirl flow generator 22 composed of swirl vanes is installed inside the inlet side of the tertiary nozzle 13.
On the other hand, a venturi 23 is installed inside the pulverized coal nozzle 11, which temporarily narrows the inner diameter of the nozzle and rectifies the air for conveyance, and temporarily increases the flow velocity to convey the pulverized coal. It works to prevent the flame from returning to the inside of the pipe (backfire).
[0012]
Downstream of the venturi 23, a spindle-shaped pulverized coal concentration controller 24 formed by inflating the vicinity of the tip of the oil gun 20 is installed, thereby narrowing the inner peripheral flow path of the pulverized coal nozzle 11 so that the coal particles The primary air 17 consisting of a mixed flow of air and air is brought closer to the outer periphery.
[0013]
Since the flow path expands from the tip of the pulverized coal concentration controller 24 into the furnace 10, the air spreads in the radial direction in the primary air 17 ejected from the pulverized coal nozzle 11, and the ejection speed decreases. However, since the pulverized coal goes straight due to the inertial force, the pulverized coal concentration on the outer peripheral side increases near the outlet of the pulverized coal nozzle 11.
[0014]
A flame holder 25 is provided at the outlet of the pulverized coal nozzle 11. The flame holder 25 includes a ring-shaped member partially protruded from the outlet of the secondary nozzle 12 and the ring-shaped member. Of the ring-shaped member, and a rectangular protrusion 26 protruding toward the center of the pulverized coal nozzle 11 is formed on the inner peripheral end surface of the ring-shaped member. , A plurality are provided along the circumferential direction.
[0015]
The flame holder 25 acts as an obstacle to the flow of the primary air 17 and the secondary air 18, whereby the pressure on the downstream side of the flame holder 25 decreases, and the primary air 17 and the secondary air 18 are ejected. This creates a region (reverse flow region) in which a flow opposite to the direction (reverse flow) appears, and as a result, during combustion, high-temperature combustion gas stays in this reverse flow region, so that the action of promoting the ignition of pulverized coal can be obtained. To.
[0016]
The secondary air 18 and the tertiary air 19 become air necessary for complete combustion of the pulverized coal ejected into the furnace 10. At this time, the tertiary air 19 is ejected while being swirled by the swirling flow generator 22. Therefore, after being ejected from the tertiary nozzle 13, it is separated from the central axis by centrifugal force, and in the vicinity of the burner, as shown by the low concentration portion 36 and the high concentration portion 37 in FIG. Therefore, the air necessary for complete combustion is insufficient and a reducing atmosphere 28 is formed downstream of the pulverized coal ignition region 27.
[0017]
As mentioned above, the nitrogen in the coal is HCN and NH during the pyrolysis reaction at the initial stage of combustion. _Three In the reducing atmosphere 28, these nitrogen compounds are harmless by reducing NOx by a NOx reduction reaction. ₂ This NOx reduction reaction is promoted as the oxygen concentration is lower and the temperature is higher.
Therefore, the formation of the reducing atmosphere 28 can suppress the generation of NOx in pulverized coal combustion.
[0018]
The tertiary air 19 is separated from the burner and the swirling flow velocity is attenuated as it advances downstream, and is mixed with pulverized coal flowing near the central axis to form an oxidizing atmosphere 29.
Thus, by mixing the tertiary air 19 and the pulverized coal, the air necessary for complete combustion is supplied to the pulverized coal, and the unburned portion remaining in the pulverized coal at the outlet of the furnace 10 (hereinafter referred to as unburned in ash). ) Decreases.
[0019]
Normally, the furnace 10 is charged with 1.1 to 1.2 times the amount of air necessary for complete combustion of pulverized coal so that the unburned ash is sufficiently suppressed. Furthermore, in this conventional example, air is supplied separately from primary, secondary, and tertiary, and this adjusts the oxygen concentration in the flame, so optimal combustion that can sufficiently suppress NOx and unburned in ash The state can be easily formed.
[0020]
Next, the prior art described in Japanese Patent Laid-Open No. 9-159109 will be described with reference to FIGS. 15 and 16. Here, FIG. 15 is a side sectional view including the central axis (shown by a broken line) of the pulverized coal burner. FIG. 16 is a front view of the pulverized coal burner nozzle as viewed along the central axis. In these drawings, 38 is a swivel generator, 39 is a current plate, and other configurations are shown in FIGS. This is the same as the prior art described in.
[0021]
The swirl generator 38 is installed in the pulverized coal nozzle 11, thereby turning the primary air 17 including the primary air and the pulverized coal, and collecting the pulverized coal on the outer peripheral side by centrifugal force to form a high concentration region. Then, in order to prevent the pulverized coal from being scattered when it is ejected from the pulverized coal nozzle 11, a flow regulating plate 39 is provided so that the swirling is stopped and then ejected. .
[0022]
Therefore, in this case, as shown in FIG. 16, a portion 37 having a locally high density is formed on a part of the outer periphery.
At this time, since the rectifying plate 39 needs to suppress only the swirling of the primary air 17 and prevent the flow from being disturbed, the rectifying plate 39 is usually made of a thin plate as much as possible.
[0023]
[Problems to be solved by the invention]
The above prior art has not been sufficiently considered for the promotion of ignition of pulverized coal ejected from a burner and the formation of a reducing atmosphere, and there has been a problem that frustration remains in suppressing NOx.
As explained in the above prior art, the formation of the reducing atmosphere 28 in the flame is important for the suppression of NOx, and in order to further reduce the NOx, the pulverized coal is ignited quickly, the primary air is consumed and the high temperature is increased. It is necessary to form the reduction region 28.
[0024]
In addition, the acceleration of ignition and the high temperature of the flame accelerate the combustion reaction and suppress unburned components in the ash, so that the promotion of ignition is a point for improving the combustion performance.
That is, in order to suppress NOx generated by pulverized coal combustion, it is first necessary to accelerate the ignition of pulverized coal. Here, in the above-described prior art, the concentration of pulverized coal at the outer peripheral portion is increased. Although the ignition at the outer periphery of the pulverized coal jet spouted from is accelerated, the fuel concentration is low at the center and the ignition is delayed, so the formation of the NOx reduction region is also delayed.
[0025]
In addition, when the pulverized coal jet is swirled as in the above-described prior art, the pulverized coal may be scattered in the radial direction by centrifugal force after being ejected from the pulverized coal nozzle, and at this time, the scattered pulverized coal is Since combustion occurs in a region with a high oxygen concentration around the pulverized coal jet, the NOx concentration becomes high.
Moreover, pulverized coal is likely to be scattered even when the pulverized coal concentration in the outer peripheral portion of the pulverized coal jet is extremely increased.
[0026]
An object of the present invention is to provide a pulverized coal burner that can easily expand the NOx reduction region and sufficiently suppress the amount of NOx generated, and a combustion apparatus using the pulverized coal burner.
[0027]
[Means for Solving the Problems]
The purpose is pulverized coal A pulverized coal nozzle through which primary air flows, a secondary air nozzle disposed concentrically on the outer periphery of the pulverized coal nozzle, and a flame holder disposed at the nozzle outlet on the outer peripheral side of the pulverized coal nozzle. The primary air containing pulverized coal is ejected from the pulverized coal nozzle to the furnace In the pulverized coal burner, the pulverized coal nozzle A plate-like member formed radially from the central axis toward the outer periphery is provided inside, and a jet of primary air containing pulverized coal flowing in the pulverized coal nozzle on the downstream side of the plate-like member in the pulverized coal nozzle The concentration distribution in the circumferential direction is such that a high concentration portion and a low concentration portion of pulverized coal exist in the circumferential direction with respect to the central axis of the burner, and on the downstream side of the plate-like member in the pulverized coal nozzle, In a cross section perpendicular to the jet of primary air containing pulverized coal flowing in the pulverized coal nozzle, the high concentration portion of the pulverized coal is directed from the central axis toward the outer periphery. This is achieved by forming them radially.
[0028]
At this time, an oil gun that supplies fuel oil to the furnace through the pulverized coal nozzle inside the pulverized coal nozzle, a venturi that narrows the inner diameter of the pulverized coal nozzle, and downstream of the venturi, the oil gun Even if it is provided with a pulverized coal concentration controller formed by inflating the vicinity of the tip of the Achieved.
[0029]
Furthermore, the above purpose is A pulverized coal nozzle having a substantially square cross section, two air nozzles having a substantially square cross section disposed on both sides of the pulverized coal nozzle, and a partition wall that partitions the pulverized coal nozzle and the air nozzle. In the pulverized coal burner, an end portion of the partition wall is formed by being bent in a direction away from the burner central axis, a plurality of parallel plate members are provided inside the pulverized coal nozzle, and the parallel plate members are arranged as described above. The primary air jet containing the pulverized coal ejected from the pulverized coal nozzle is arranged in the direction sandwiched by the individual air nozzles in parallel with an interval, and the high-concentration portion of the pulverized coal It is alternately formed by low concentration portions, and the high concentration portion of pulverized coal includes a straight line directed to the two air nozzles, and is formed in parallel with this straight line. This is also achieved.
[0030]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the pulverized coal burner according to the present invention and a combustion apparatus using the pulverized coal burner will be described in detail with reference to the illustrated embodiments. However, the present invention is not limited to these embodiments.
[0031]
1 and 2 show a first embodiment of a pulverized coal burner according to the present invention. Here, FIG. 1 is a side sectional view including a central axis of the pulverized coal burner, and FIG. 2 is a central axis of the pulverized coal burner. 1 is a front view from the direction and corresponds to a view seen from the direction of arrow X in FIG. 1. In these figures, 30 is a plate-like member, and the other components are shown in FIG. 13 and FIG. Same as the prior art.
[0032]
As already explained, the formation of the reducing atmosphere 28 in the flame is important for the suppression of NOx. Further, in order to reduce NOx, it is necessary to ignite pulverized coal quickly and consume primary air to form a high temperature reduction region 28. In addition, the acceleration of ignition and the high temperature of the flame accelerate the combustion reaction and suppress the unburned content in the ash. For this reason, promotion of ignition is a point for improving combustion performance.
[0033]
Therefore, in this embodiment, the plate-like member 30 is provided so that the ignition of the pulverized coal is promoted and the temperature of the flame is increased. The pulverized coal concentration adjuster 24 in the nozzle 11 is attached radially to the outer peripheral end face from the central axis.
[0034]
Next, the details of the plate-like member 30 will be described. First, FIG. 3A is an enlarged view of a part of the pulverized coal nozzle 11 in FIG. 1, and FIG. It is a figure and FIG. (c) shows the plate-like member 30 FIG. It is the figure seen from the arrow Y direction of (b).
[0035]
As is apparent from these drawings, the plate-like member 30 includes a front edge portion 31 whose thickness increases along the flow of the primary air 17, a central portion 32 having a considerable thickness of 10 mm or more, and a plate It is formed by the trailing edge 33 whose thickness is decreasing.
[0036]
Here, the front edge portion 31 and the rear edge portion 33 are provided so that the primary air 17 passing through the pulverized coal nozzle 11 passes along the surface of the plate-like member 30 smoothly without causing separation. The cross-sectional shape is such that the plate thickness gradually changes in the flow direction.
[0037]
As a result, the primary air 17 in the pulverized coal nozzle 11 flows along the plate-like member 30 as shown in FIG. 3C, and is accelerated because the flow path is narrowed here.
As described above, the primary air 17 is a mixture of pulverized coal and air. The air in the primary air 17 passes through the plate-like member 30 and then expands the flow path, as indicated by the dashed arrow 35. It spreads and flows.
[0038]
On the other hand, the pulverized coal in the primary air 17 travels as indicated by an arrow 34 because the pulverized coal travels straight by the inertial force after passing through the plate-like member 30, and for this reason, the concentration of the pulverized coal is downstream in the plate-like member 30. The pulverized coal concentration is increased in the downstream portion of the flow path sandwiched between the plate-like members 30 and the low concentration portion 36 and the high concentration portion 37 are formed.
[0039]
Here, as shown in FIG. 3 (a), the plate-like member 30 is provided radially from the central axis. For this reason, the primary air 17 is jetted at the outlet of the pulverized coal nozzle 11. When viewed in a vertical cross section, as shown in FIG. 2, the pulverized coal concentration in the primary air 17 has a distribution in the circumferential direction with respect to the center of the nozzle, and the low concentration portion 36 and the high concentration portion 37 are centered. It is formed radially from the shaft.
[0040]
In the prior art shown in FIG. 13, as shown in FIG. 14, the pulverized coal concentration in the outer peripheral portion is increased, but the pulverized coal concentration in the central portion is lowered, so that the high concentration portion 37 is formed in the peripheral portion. At this time, in the prior art of FIG. 15, the swirl generator 38 swirls the primary air 17 and collects the pulverized coal in the primary air 17 by the centrifugal force on the outer periphery. As a result of stopping the turning by the rectifying plate 39, as shown in FIG. 16, a portion having a high pulverized coal concentration is distributed on the outer peripheral portion, and a high concentration portion 37 is locally formed. It will be.
[0041]
FIG. 4 (a) shows the measurement result of the pulverized coal concentration distribution at the outlet of the pulverized coal nozzle, with the radial distance (r / r) on the vertical axis. ₀ ), And the horizontal axis represents the relative concentration. Where r ₀ Is the radius of the pulverized coal nozzle, r is the radial distance from the central axis, and the relative concentration on the horizontal axis is the ratio of the amount of pulverized coal to the amount of air in the supplied mixed flow, and each measurement position It shows the ratio of the amount of pulverized coal and the amount of air.
[0042]
The measurement conditions at this time are as follows. First, in the embodiment of FIG. 1, as shown in FIG. 4B, the measurement result of the pulverized coal concentration at the downstream position between the plate members 30 is A, the plate member 30. The measurement result of the pulverized coal concentration in the prior art burner shown in FIG. 13 is shown in C for comparison.
[0043]
As apparent from FIG. 4 (a), in the prior art burner, as seen in the measurement result C, the radial distance (r / r ₀ ) = 1, the concentration of pulverized coal in the inner periphery is about 1.2 times the average concentration, which is the radial distance (r / r ₀ ) = 0.5 in the inner peripheral portion of 0.5, and the presence of the concentration distribution in the radial direction shown in FIG. 14 was confirmed.
[0044]
Next, in the burner according to the embodiment of the present invention shown in FIG. 1, in the case of the measurement result A, the radial distance (r / r ₀ ) = 0.75, the pulverized coal concentration is increased up to 1.4 times the average concentration, and in the case of measurement result B, the same radial distance (= r / r ₀ ) = 0.75, the average concentration is about 0.8 times the average concentration, and clearly the pulverized coal concentration is low downstream of the plate-like member 30, and therefore the pulverized coal concentration is radially high as shown in FIG. It was confirmed that a part was formed.
[0045]
Further, according to FIG. 4 (a), from the measurement result A and the measurement result C, the pulverized coal concentration in the central direction is compared according to the embodiment of the present invention as compared with the case where the relative concentration is 1. It can be seen that the high area is about 20% larger than the prior art.
[0046]
Returning to FIG. 1, the pulverized coal in the primary air 17 ejected from the pulverized coal nozzle 11 into the furnace 10 is ignited by the high-temperature gas staying in the reverse flow region near the flame holder 25.
The temperature of the ignited pulverized coal particles rises due to combustion, and as a result, the nearby pulverized coal particles are heated to ignite one after another, and as a result, the combustion spreads.
[0047]
The phenomenon in which this combustion spreads is called flame propagation, and this flame propagation proceeds from the outer periphery of the primary air 17 injected into the furnace 10 toward the inner periphery.
At this time, if the flame propagation proceeds to the center of the nozzle at a high speed, the entire pulverized coal is ignited quickly, leading to a reduction in NOx.
[0048]
Therefore, although the improvement of the flame propagation speed is a proposition, the flame propagation speed has a strong correlation with the concentration of pulverized coal in the primary air 17.
FIG. 5 shows the relationship between the concentration of pulverized coal obtained by experiments and the flame propagation speed. As is apparent from FIG. 5, it can be seen that the flame propagation speed increases as the pulverized coal concentration is increased.
[0049]
FIG. 5 shows the flame propagation speed when the flow rate of pulverized coal is 18 [m / s] on the vertical axis, and the horizontal axis indicates the pulverized coal concentration by the weight ratio of coal and air. The flow rate condition of 18 [m / s] is almost the same as the flow rate of the pulverized coal ejected from the primary nozzle.
[0050]
By the way, the pulverized coal burner is usually burned under the condition of C / A≈0.43 [kg / kg] with respect to the ratio C / A (Coal / Air) of the coal amount and the primary air amount. The flame propagation speed at that time is about 0.05 [m / s].
In the burner according to the prior art, as shown in FIG. 14, the flame propagation is fast because the pulverized coal concentration is high in the outer peripheral portion, but the flame propagation is slow because the pulverized coal concentration is low near the center. Will not be able to reduce NOx sufficiently.
[0051]
On the other hand, in the burner according to the embodiment of FIG. 1, the plate-like member 30 having a considerable thickness is located in the pulverized coal nozzle 11, and as a result, as shown in FIG. Since the carbon concentration has a distribution in the circumferential direction, and a portion with a high pulverized coal concentration is formed radially from the central axis, the flame propagation from the outer periphery to the central portion passes through this high concentration portion at a high speed. Propagate with.
[0052]
As a result, the ignition of the pulverized coal flowing through the central portion is accelerated, and the flame propagation here spreads from the ignited portion toward all the surrounding directions, so that the ignition of the entire pulverized coal is also accelerated.
Therefore, according to the embodiment of FIG. 1, NOx can be greatly reduced.
[0053]
Moreover, according to this embodiment, since the reduction area in the vicinity of the burner is expanded, NO accompanying combustion is increased. _X In addition, a sufficient progress of mixing can be obtained rapidly since the mixing of the complete combustion air and pulverized coal in the downstream of the reducing atmosphere can be rapidly obtained.
[0054]
Note that the pulverized coal concentration can be increased simply by reducing the amount of primary air in the mixed flow, and thus the flame propagation speed can be increased. However, since this primary air also plays a role of conveying pulverized coal, it cannot be simply reduced.
[0055]
However, in the embodiment of FIG. 1, as shown in FIG. 2, a portion having a high pulverized coal concentration is formed radially, so that the amount of air in the primary air 17 is not reduced as a whole, and a sufficient flame is achieved. Propagation speed can be increased.
[0056]
Now, assuming that the thickness of each plate-like member 30 is set so that the total cross-sectional area of the plate-like member 30 occupies about 20% of the flow passage cross-sectional area of the pulverized coal nozzle 11 in the embodiment of FIG. Thereby, the pulverized coal concentration in the dense portion 37 formed between the plate-like members 30 is increased to about 0.54 [kg / kg] in C / A, and the flame propagation speed at this time is about 0.1 [m / s], which is about twice as high as usual.
[0057]
Furthermore, when the total cross-sectional area of the plate-like member 30 occupies about 60% of the flow path cross-sectional area of the pulverized coal nozzle 11, the pulverized coal concentration in the dense portion 37 is about C / A. It becomes as high as 1.00 [kg / kg], the flame propagation speed reaches about 0.3 [m / s], and is increased to about 5 times the normal case.
[0058]
However, the flame propagation speed does not change even if it exceeds this, that is, 60% or more, and even at this 60%, the ejection speed of the primary air 17 from the pulverized coal nozzle 11 reaches 50 [m / s]. Therefore, it can be said that this is a limit from the point of wear on the inner surface of the pulverized coal nozzle 11 by the primary air 17.
[0059]
Next, FIG. 6 shows the measurement result of the gas concentration on the burner central axis. The measurement conditions are as follows: the diameter of the pulverized coal nozzle 11 is 0.167 [m], and the supply amount of pulverized coal is 500 [kg / h]. Here, the present invention is the characteristic in the case of the embodiment of FIG. 1, and the conventional example is the characteristic in the case of the prior art of FIG.
[0060]
First, the O shown in FIG. ₂ In the case of (oxygen), the ignited pulverized coal consumes oxygen abruptly, so the oxygen concentration decreases as the axial distance from the burner increases. However, it can be seen that the present invention consumes oxygen faster.
[0061]
This means that the burner according to the embodiment of the present invention shown in FIG. 1 can form the reducing atmosphere 28 earlier than the prior art burner of FIG.
As is apparent from FIG. 6 (a), in any case, the oxygen concentration decreases to 3% when the axial distance from the burner is 0.8 [m].
[0062]
Next, in the case of NOx (nitrogen oxide) shown in FIG. 6 (b), in the conventional example, the generation of nitrogen oxide is performed after the axial distance from the burner reaches the position of 0.5 [m]. In the present invention, the production of nitrogen oxide starts as early as the position of 0.3 [m], and the nitrogen oxide is produced from the position closer to the nozzle side by 0.2 [m] than the conventional example. You can see that
[0063]
This means that the ignited pulverized coal is obtained faster in the burner of the present invention than in the conventional burner.
At this time, the position where nitrogen oxide is most generated is 0.8 [m] in any burner, and thereafter, the generation decreases.
[0064]
Next, FIG. 7 shows the relationship between the NOx concentration and the combustion rate at the outlet of the combustion furnace (furnace 10) about 7 [m] downstream from the burner, and the measurement conditions are as shown.
As is apparent from FIG. 7, the NOx concentration varies depending on the combustion rate.
Therefore, when compared at a combustion rate of 99.5%, it is about 260 [ppm] in the conventional example, whereas in the present invention, it is about 205 [ppm]. Therefore, according to the present invention, NOx is reduced. It was found that 55 [ppm] can be reduced.
[0065]
By the way, as shown in FIG. 8A, the plate-like member 30 in the above-described embodiment may be left as a flat plate, and the present invention achieves the intended object also by such an embodiment. be able to.
However, as shown in FIG. 8 (a), when the plate-like member 30 is a flat plate, the pulverized coal particles collide vertically with the upstream end face, and the flow is easily separated at the downstream end face. These things disturb the flow of pulverized coal, and there is a possibility that it may hinder the formation of a concentration distribution in the circumferential direction of the pulverized coal.
[0066]
Therefore, as an embodiment of the present invention, as shown in FIG. 3, the plate thickness gradually increases at the front edge portion 31 and gradually decreases at the rear edge portion 33 along the flow of the primary air 17. The plate-shaped member 30 having a shape to be used is desirable.
In the plate-like member 30 shown in FIG. 3, the pulverized coal collides obliquely with the side surface of the front edge portion 31, so that wear of the plate-like member 30 can be suppressed.
[0067]
Moreover, since primary air flows along the plate-shaped member 30 in the rear edge part 33, isolation | separation with pulverized coal is obtained smoothly.
Here, in the case of the plate-like member 30 in FIG. 3, the front edge portion 31 receives the wear resistant material, and the rear edge portion 33 receives the radiant heat from the furnace 10, so that the heat resistant material can be pasted. desirable.
[0068]
Further, the plate-like member 30 has a wing shape as shown in FIG. 8 (b), and does not have the central portion 32 shown in FIG. 3 as shown in FIG. You may use the shape which consists only of the edge part 31 and the rear edge part 33. FIG.
[0069]
On the other hand, the installation position of the plate member 30 in the pulverized coal nozzle 11 and the length in the direction along the flow of the primary air 17 are not limited to the embodiment of FIG. Can be set.
[0070]
For example, the plate-shaped member 30 may have a shape that does not reach the outlet and reaches the middle of the flow path. At this time, when the concentration distribution controller 24 is inserted, a high concentration region of pulverized coal is formed at the outer peripheral portion of the jet and the downstream portion of the plate member 30 at the nozzle outlet.
[0071]
Further, the plate-like member 30 may be provided on the upstream side or the downstream side of the concentration distribution regulator 24.
In this case, since the flow path is wider than in the case of FIG. 3, the flow rate of the primary air is further reduced, and as a result, wear of the nozzles and pressure loss can be reduced.
[0072]
Here, when the plate-like member 30 is moved to the upstream side, after passing through the plate-like member 30, remixing of pulverized coal and primary air occurs in the state of being in the pulverized coal nozzle 11 again, Compared with the case of FIG. 3, the density difference is reduced.
[0073]
On the other hand, when the plate-like member 30 is brought closer to the furnace 10 side, the temperature is likely to rise due to radiant heat from the inside of the furnace, so it is desirable that the plate-like member 30 be installed as far as possible from the nozzle outlet. It is only necessary to install the pulverized coal nozzle 11 away from the outlet of the pulverized coal nozzle 11 by 0.5 to 1.0 times the nozzle diameter.
However, if the plate-like member 30 is installed away from the nozzle outlet in this way, a space for attenuating the flow rate of the pulverized coal is created, and this needs to be taken into consideration.
[0074]
By the way, in the embodiment shown in FIG. 1, the two air nozzles of the secondary nozzle 12 and the tertiary nozzle 13 are provided. However, the present invention may be implemented as a burner having one air nozzle. Alternatively, the concentration distribution controller 24 may be omitted.
[0075]
Next, another embodiment of the present invention will be described.
9 and 10 show a second embodiment of the pulverized coal burner according to the present invention. Here, FIG. 9 is a side sectional view including the central axis of the pulverized coal burner, and FIG. 10 shows the central axis of the pulverized coal burner. 9 is a front view from the direction and corresponds to a view seen from the direction of arrow X in FIG. 9. In these figures, 40 is a parallel plate member, 41 is an air nozzle, 42 is a partition wall, and 43 is a burner throat. The other components are the same as those of the first embodiment shown in FIGS.
[0076]
In this embodiment, as is clear from FIG. 10 in particular, the pulverized coal nozzle 11 has a substantially square (square or rectangular) cross-sectional shape, and has two opposing surfaces, the upper and lower surfaces in the figure. After being partitioned by the partition wall 42, it is formed in a shape sandwiched by a pair of air nozzles 41 having a rectangular cross section.
[0077]
Therefore, in this embodiment, the pulverized coal nozzle 11 is formed as a flow path surrounded by the side walls of the partition wall 42 and the burner throat 43, and the air nozzle 41 is also formed as a flow path surrounded by the partition wall 42 and the burner throat 43. Yes.
[0078]
The primary air 17 is supplied to the pulverized coal nozzle 11 as in the case of FIG. 1, but the combustion air 44 is supplied from the air blower (not shown) to the wind box 21 and then ejected from the air nozzle 41. At this time, the partition wall 42 is bent at the end of the furnace 10 in the direction away from the central axis as shown in the figure, so that the combustion air 44 is ejected from the air nozzle 41. In doing so, it flows as indicated by the arrow 45, and therefore flows away from the flow of pulverized coal indicated by the arrow 46.
[0079]
At this time, since the downstream side of the partition wall 42 becomes an obstacle to the flow of the primary air air 17, a pressure drop occurs on the downstream side of the partition wall 42.
As a result, a flow of pulverized coal and a flow opposite to the direction of jetting of combustion air (reverse flow) are generated here, which causes retention of high-temperature combustion gas during combustion and promotes ignition of pulverized coal. The
[0080]
The combustion air 44 is supplied in an amount required for complete combustion of the pulverized coal. At this time, the combustion air 44 flows away from the pulverized coal flowing near the central axis in the vicinity of the burner. In the downstream portion of the ignition region 27, the air necessary for complete combustion is insufficient, and a reducing atmosphere 28 is formed.
The NOx reduction reaction proceeds in the reducing atmosphere 28.
[0081]
As already explained, this NOx reduction reaction is promoted as the oxygen concentration is lower and the temperature is higher, so to reduce NOx, the pulverized coal is ignited earlier and the primary air is consumed to form a high temperature reduction region. There is a need to.
In addition, the acceleration of ignition and the high temperature of the flame accelerate the combustion reaction and suppress the unburned content in the ash.
[0082]
For this reason, the promotion of ignition is a point for improving the combustion performance. In the embodiment of FIG. 9, the parallel plate-like member 40 is sandwiched between the air nozzles 41 on both sides in the pulverized coal nozzle 11 (hereinafter, referred to as the following) This parallel plate-like member 40 has a plate thickness that changes in the upstream portion and the downstream portion with respect to the flow of the primary air 17, and about 10 in the central portion. [Mm] It is made into a shape having a flat plate portion.
[0083]
As a result, the primary air 17 is accelerated because the flow path is narrowed between the parallel plate-like members 40, and then, after passing through the parallel plate-like member 40, the primary air 17 tries to spread and flow along with the enlargement of the flow path.
[0084]
However, at this time, the pulverized coal in the primary air 17 travels straight after passing through the parallel plate-like member 40 due to the inertial force, so that the pulverized coal concentration in the downstream portion of the parallel plate-like member 40 decreases and becomes parallel. The pulverized coal concentration increases in the downstream portion of the flow path sandwiched between the plate-like members 40.
[0085]
For this reason, as shown in FIG. 10 as seen from the cross section perpendicular to the jet of primary air at the outlet of the pulverized coal nozzle 11, that is, from the direction of the arrow XX in FIG. The high-concentration portions 37 are formed in the same portion as the plate-like member 40 and in parallel between the parallel plate-like members 40 in the longitudinal direction.
[0086]
The pulverized coal ejected by the primary air 17 is ignited by the high-temperature gas staying in the backflow portion downstream of the partition wall 42, and flame propagation starts. At this time, the flame propagation proceeds from the outer periphery toward the inner periphery.
Therefore, if this flame propagation proceeds to the center of the nozzle quickly, ignition of the entire pulverized coal is accelerated, leading to a reduction in NOx.
[0087]
According to the embodiment of FIG. 9, as is clear from FIG. 10, the high concentration portion 37 in which pulverized coal is densely distributed is formed toward the central axis. It travels at high speed along the road and reaches the central axis in a short time.
Further, since the flame propagation proceeds simultaneously in all directions, the ignition of the entire pulverized coal also proceeds faster than in the case of a uniform concentration distribution.
[0088]
For this reason, after ejecting from the pulverized coal nozzle, the pulverized coal is quickly ignited and consumes oxygen, and as a result, the region of the reducing atmosphere 28 is greatly expanded upstream. Therefore, according to this embodiment, the amount of NOx produced Can be sufficiently suppressed.
[0089]
By the way, in this embodiment, unlike the embodiment of FIG. 1, the pulverized coal concentration adjuster 24 is not provided in the pulverized coal nozzle 11. The operational effects of providing this can also be expected.
[0090]
In the present embodiment, the concentration distribution controller is not provided in the pulverized coal nozzle, but the same effect can be obtained when the concentration distribution controller 24 is provided as in the first embodiment. Further, when the plate-like member 30 is provided radially, the same effect is obtained.
[0091]
Next, a combustion apparatus according to the present invention will be described with reference to illustrated embodiments.
Although the pulverized coal burner by the said embodiment is used for combustion apparatuses, such as various incinerators, FIG. 11 is the 1st of the combustion apparatus using the pulverized coal burner by one Embodiment of this invention demonstrated above. In FIG. 11, the burner 50 is, for example, according to the embodiment of the present invention described in FIG.
[0092]
The burner 50 is supplied with primary air 17 composed of a mixed flow of pulverized coal and conveying air through a pulverized coal pipe 51.
For this reason, the coal carried from the coal storage 53 is made into pulverized coal by the pulverizer 54, conveyed by the air supplied from the blower 55, supplied to the burner 50 through the pulverized coal pipe 51, and from the nozzle to the furnace 10 Is erupted.
[0093]
On the other hand, the combustion air is supplied by another blower 56, and at this time, a part is supplied to the burner 50 to become secondary air and tertiary air, but the rest is downstream in the furnace 10 from the burner 50. Is supplied to an air supply port 57 provided in the furnace 10 and supplied from here to the furnace 10.
[0094]
If the air is divided and supplied to the furnace 10 in this way, oxygen is insufficient in the vicinity of the burner 50, and as a result, the reducing atmosphere 28 is easily formed. This is because the amount of unburned ash in the ash can be reduced by the addition, and such a combustion method is called a two-stage combustion method.
[0095]
By the way, in this two-stage combustion method, first, about 0.7 to 0.95 times the air necessary for complete combustion of pulverized coal is introduced from the burner 50, and then the remaining air is supplied from the air supply port 57. The air is charged, and the air required for the complete combustion of the pulverized coal is about 1.1 to 1.25 times as much as the entire furnace, whereby the complete combustion of the differential coal is obtained in the complete combustion atmosphere 58. To do so.
[0096]
Next, FIG. 12 is another example of the combustion apparatus to which the pulverized coal burner according to the present invention is applied. In this combustion apparatus, the air supply port 57 in the combustion apparatus of FIG. The necessary total amount of air is supplied, and this method is called a single stage combustion system.
[0097]
In this single-stage combustion method, the amount of NOx emitted from the furnace 10 is larger than that in the two-stage combustion system, but the oxygen concentration on the wall surface of the furnace 10 is increased. Since corrosion (sulfurization corrosion) is suppressed, there is an advantage that the service life of the furnace can be extended.
[0098]
As described above, in both cases of the two-stage combustion system and the single-stage combustion system, the combustion apparatus forms a high-temperature reducing atmosphere 28 in the flame in order to reduce NOx, and the nitrogen content in the pulverized coal. NH _Three It is necessary to release NOx as a reducing substance such as HCN and promote the reduction reaction of NOx to nitrogen.
[0099]
Here, in these FIG. 11 and FIG. 12, the ignition of pulverized coal is accelerated by applying, for example, the pulverized coal burner according to the embodiment of the present invention described in FIG.
Therefore, according to the combustion apparatus shown in FIG. 11 and FIG. 12, the consumption of oxygen in the vicinity of the burner 50 can be accelerated, and the region where the reducing atmosphere 28 is formed can be widened. The amount can be reduced.
[0100]
Further, according to the combustion apparatus shown in FIGS. 11 and 12, since the ignition time can be accelerated, the combustion time in the furnace 10 can be lengthened, so that the combustion proceeds sufficiently and the unburned amount in the ash is reduced. Can.
[0101]
11 and 12, the embodiment of the pulverized coal burner according to the present invention shown in FIG. 1 is applied. However, the embodiment of the pulverized coal burner according to the present invention described in FIG. 9 is described. Needless to say, the above may be applied.
[0102]
【The invention's effect】
According to the present invention, the ignition of the pulverized coal can be sufficiently promoted with a simple configuration, and the reduction region can be enlarged in the vicinity of the burner. _X It is possible to easily provide a pulverized coal burner in which the occurrence of ash is sufficiently reduced.
As a result, according to the present invention, the progress of the mixing of the complete combustion air and the pulverized coal in the downstream of the reducing atmosphere can be rapidly obtained, so that the combustion rate can be sufficiently improved.
[Brief description of the drawings]
FIG. 1 is a side sectional view showing a first embodiment of a pulverized coal burner according to the present invention.
FIG. 2 is a front view showing a first embodiment of the present invention.
FIG. 3 is an explanatory diagram of a plate-like member according to the first embodiment of the present invention.
FIG. 4 is a characteristic diagram for explaining the operation of the first exemplary embodiment of the present invention.
FIG. 5 is a characteristic diagram for explaining the operation of the first exemplary embodiment of the present invention.
FIG. 6 is a characteristic diagram for explaining the operation of the first exemplary embodiment of the present invention.
FIG. 7 is a characteristic diagram for explaining the operation of the first exemplary embodiment of the present invention.
FIG. 8 is an explanatory diagram of a plate-like member according to the first embodiment of the present invention.
FIG. 9 is a side sectional view showing a second embodiment of the pulverized coal burner according to the present invention.
FIG. 10 is a front view showing a second embodiment of the present invention.
FIG. 11 is an explanatory view showing a first embodiment of a combustion apparatus according to the present invention.
FIG. 12 is an explanatory view showing a second embodiment of the combustion apparatus according to the present invention.
FIG. 13 is a side sectional view showing an example of a pulverized coal burner according to the prior art.
FIG. 14 is a front view showing an example of a pulverized coal burner according to the prior art.
FIG. 15 is a side sectional view showing another example of a pulverized coal burner according to the prior art.
FIG. 16 is a front view showing another example of a pulverized coal burner according to the prior art.
[Explanation of symbols]
10 Furnace
11 Pulverized coal nozzle
12 Secondary nozzle
13 Tertiary nozzle
14 Primary throat
15 Secondary throat
16 Tertiary throat
17 Primary air (mixed flow of pulverized coal and transport air)
18 Secondary air
19 Tertiary air
20 Oil gun
21 Wind box
22 Swirl generator
23 Venturi
24 Pulverized coal concentration controller
25 Flame holder
26 Protrusions
27 Ignition atmosphere
28 Reducing atmosphere
29 Oxidizing atmosphere
30 Plate-shaped member
31 Front edge of plate
32 Parallel parts of plate-like members
33 Rear edge of plate-like member
34, 35 arrows
36 Low concentration part
37 High concentration part
38 Swivel generator
39 Current plate
40 Parallel plate members
41 Air nozzle
42 Bulkhead
43 Burnathroat
44 Combustion air
45, 46 arrows
50 burner
51 pulverized coal pipe
52 Air supply pipe
53 Coal storage
54 Pulverized coal pulverizer
55, 56 Blower
58 Complete combustion atmosphere

Claims (3)

A pulverized coal nozzle through which primary air containing pulverized coal flows, a secondary air nozzle disposed concentrically around the outer periphery of the pulverized coal nozzle, and a flame holder disposed at the nozzle outlet on the outer peripheral side of the pulverized coal nozzle, In a pulverized coal burner that ejects primary air containing pulverized coal from a pulverized coal nozzle to a furnace ,
In the pulverized coal nozzle is provided a plate-like member formed radially from the central axis toward the outer periphery,
The concentration distribution in the circumferential direction of the jet of primary air containing pulverized coal flowing in the pulverized coal nozzle on the downstream side of the plate-like member in the pulverized coal nozzle is expressed in the circumferential direction with respect to the central axis of the burner. So that there are high and low concentration parts,
In a cross section perpendicular to the jet of primary air containing pulverized coal flowing in the pulverized coal nozzle on the downstream side of the plate-like member in the pulverized coal nozzle, the high concentration portion of the pulverized coal is outer periphery from the central axis. A pulverized coal burner, characterized in that it is formed radially toward the surface. A pulverized coal burner according to claim 1,
An oil gun for supplying fuel oil to the furnace through the pulverized coal nozzle inside the pulverized coal nozzle;
A pulverized coal burner comprising: a venturi that narrows the inner diameter of the pulverized coal nozzle; and a pulverized coal concentration controller formed by inflating the vicinity of the tip of the oil gun downstream of the venturi . A pulverized coal nozzle having a substantially square cross section, two air nozzles having a substantially square cross section disposed on both sides of the pulverized coal nozzle, and a partition wall that partitions the pulverized coal nozzle and the air nozzle. In a pulverized coal burner ,
The end of the partition is formed by bending in a direction away from the burner central axis,
A plurality of parallel plate-like members are provided inside the pulverized coal nozzle,
By arranging the parallel plate-like members in the direction sandwiched between the two air nozzles in parallel with an interval, a jet of primary air containing pulverized coal ejected from the pulverized coal nozzle is generated. , Alternately formed by high and low concentration parts of pulverized coal,
A high concentration portion of pulverized coal includes a straight line toward the two air nozzles;
A pulverized coal burner configured to be formed in parallel with the straight line .

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