JP2014167353A - Stoker furnace recirculated exhaust gas supply control method and stoker furnace - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a stoker furnace recirculated exhaust gas supply control method and a stoker furnace capable of performing a substantial reduction of NOx concentration at a furnace outlet without increasing CO concentration.SOLUTION: A recirculated exhaust gas fed from a front side is supplied from a front side ceiling wall rearward and a recirculated exhaust gas fed from a rear side is supplied from a rear wall or a rear side ceiling wall forward, respectively. A distribution of temperature in a combustion chamber is measured to calculate at which position a combustion position on a fire grade is located in a forward or rearward direction with respect to a prescribed reference range. A distribution ratio between the recirculated exhaust gas from the front side and the recirculated exhaust gas from the rear side is changed according to the cases, i.e. a case in which the combustion position is located at a forward position, a case in which the combustion position is located at a rearward position and a case in which the combustion position is located within the reference range.

Description

  TECHNICAL FIELD The present invention relates to a recirculation exhaust gas supply control method for a stoker furnace and a stoker furnace, and more particularly to a recirculation exhaust gas in a stoker furnace that is used for waste combustion and the like and has a problem of reducing CO and NOx in exhaust gas. The present invention relates to a supply control method and a stoker furnace capable of appropriate recirculation exhaust gas supply control.

  In Patent Document 1, exhaust gas discharged from a stoker furnace (referred to as “recirculated exhaust gas” in this specification) is supplied above the grate in the stoker furnace, so that nitrogen oxide (hereinafter referred to as “NOx”). The operation method which suppresses this is disclosed.

  Patent Document 2 discloses an operation method that suppresses the generation of CO by supplying an appropriate amount of secondary air to the secondary combustion chamber of the stoker furnace and supplying recirculated exhaust gas to the secondary combustion chamber. It is disclosed.

  Patent Document 3 discloses that an ignition position (combustion start position) and a burnout position are obtained using an infrared camera, and position control of the ignition position and the like is performed.

JP 59-44513 A Japanese Patent Laid-Open No. 5-113208 Japanese Patent No. 3916450

  As disclosed in Patent Document 1, it is possible to suppress NOx by supplying recirculated exhaust gas as compared with the case of supplying only secondary air. For example, for a stoker furnace that performs waste incineration When a significant reduction target of NOx concentration at the furnace outlet (a strict target value such as 20 ppm or less) is set, it is difficult to achieve the target only by controlling the supply amount of the recirculated exhaust gas. In addition, when the supply amount of the recirculated exhaust gas is controlled so as to reduce the NOx concentration, the CO concentration may increase, which makes it difficult to control to achieve the target.

  An object of the present invention is to provide a recirculation exhaust gas supply control method for a stoker furnace and a stoker furnace that can greatly reduce the NOx concentration at the furnace outlet without increasing the CO concentration.

  A recirculation exhaust gas supply control method for a stoker furnace according to the present invention is provided at a lower primary combustion chamber to which primary air is supplied, an upper secondary combustion chamber to which secondary air is supplied, and a bottom of the primary combustion chamber. The primary combustion chamber has a front wall provided with a charging hopper, a front ceiling wall, a rear wall, and a rear ceiling wall, and the recirculated exhaust gas is disposed in the primary combustion chamber. In a stoker furnace that supplies the recirculated exhaust gas, a method for controlling the supply of the recirculated exhaust gas from the front ceiling wall to the rear and the rear recirculated exhaust gas from the rear wall or the rear ceiling wall to the front The recirculated exhaust gas from each side is supplied, the temperature distribution in the primary combustion chamber is measured, and at least one of the combustion start position and the burnout position on the grate is in the front-rear direction with respect to a preset reference range How much If at least one of the combustion start position and the burnout position is at the front of the reference range, at the rear, and at the reference range, it is divided into at least three cases. The distribution ratio between the recirculated exhaust gas from the front side and the recirculated exhaust gas from the rear side is changed depending on the case.

  In the present invention, when it is not necessary to distinguish between the primary combustion chamber and the secondary combustion chamber, they are simply referred to as combustion chambers.

  The stoker furnace according to the present invention includes a lower primary combustion chamber to which primary air is supplied, an upper secondary combustion chamber to which secondary air is supplied, and a plurality of grate installed at the bottom of the primary combustion chamber. The primary combustion chamber has a front wall provided with a charging hopper, a front ceiling wall, a rear wall, and a rear ceiling wall, and supplies a recirculated exhaust gas into the primary combustion chamber. A recirculated exhaust gas supply device for supplying recirculated exhaust gas from the front side toward the rear from the front ceiling wall and a recirculated exhaust gas supply from the rear side toward the front from the rear wall or the rear ceiling wall, and a primary A temperature distribution measuring device for measuring the temperature distribution in the combustion chamber; and a control device for controlling the combustion so as to reduce the CO concentration and the NOx concentration. Temperature distribution of A combustion position calculation unit that calculates at least one of a combustion start position and a burnout position, and a recirculation exhaust gas control unit that controls the supply amount of the recirculation exhaust gas. Find at least one of the upper combustion start position and burnout position in the front-rear direction with respect to a preset reference range, and compare at least one of the combustion start position and burnout position with the reference range. In this case, it is divided into at least three cases: the front side, the rear side, and the rear range, and the distribution of the recirculated exhaust gas from the front side and the recirculated exhaust gas from the rear side according to each case. It is characterized by changing the ratio.

  In this invention, in order to perform preferable control, first, recirculated exhaust gas is supplied into the primary combustion chamber from the front side and the rear side. In addition, in order to specify what the current combustion state is, a reference range of the combustion start position and / or the burnout position is set in advance. The combustion start position and burnout position on the grate can be obtained by measuring the temperature distribution in the primary combustion chamber. The temperature distribution in the primary combustion chamber is preferably measured with an infrared camera. The grate is distinguished from the front side from the drying stage, the combustion stage, and the post-combustion stage. Normally, combustion starts in the portion from the final position of the drying stage to the front side position of the combustion stage, and almost in the rear part of the combustion stage. After burning, it burns out in the post-combustion stage.

  In the present invention, the NOx concentration at the furnace outlet can be significantly reduced without increasing the CO concentration, so that the combustion position (combustion start position and / or burnout position) on the grate that changes from time to time can be obtained. Pay attention and determine where the current combustion position is in the front-rear direction, and if the combustion position is at the front of the reference range, at the rear, and at least three in the reference range Cases shall be divided. In such case classification, when the combustion position is at the front, the CO concentration tends to increase compared to when the combustion position is at the reference range and the rear, and the increase in CO is increased. It turned out that control to suppress is necessary. That is, when the combustion position is closer to the front, appropriate control is possible by performing control different from the other cases, and the NOx concentration can be greatly reduced as compared with the case where the combustion position is not divided. An increase in CO concentration can be prevented.

  In the case classification, the combustion start position is the front side. However, when the burnout position is the rear side, it is preferable that the control is different from the front side, the reference range, and the rear side as “wide area”. . When divided into four cases: front, reference range, rear, and wide area, the distribution ratio is usually different for the front case and the other three cases. For the two cases, two or three of the cases may have the same distribution ratio as required.

  As a specific control method, when the combustion start position is closer to the reference range, the amount of recirculated exhaust gas from the front side is lowered, the amount of recirculated exhaust gas from the rear side is increased, and the combustion start position is the reference. When it is behind the range, it is preferable to control so that the amount of recirculated exhaust gas from the front side is increased and the amount of recirculated exhaust gas from the rear side is decreased.

  This makes it possible to significantly reduce the NOx concentration regardless of the combustion start position, and to suppress the increase in CO concentration when the combustion start position where the CO concentration increases is closer to the front. it can.

  The distribution ratio of the recirculated exhaust gas is, for example, about 30/70 to 40/60 in the case of the front, and is about 50/50 to 40/60 in other cases. Values other than the distribution ratio of the recirculated exhaust gas may be set as appropriate. For example, the recirculated exhaust gas ratio is 10 to 35%, the primary air ratio is 0.7 to 1.2, and the total air ratio is 1.1 to 1.40, the temperature at the outlet of the primary combustion chamber is set to 900 to 1100 ° C., the combustion efficiency at the outlet of the primary combustion chamber is set to 80 to 98%, and the temperature on the upstream side of the secondary combustion chamber is set to 850 to 1100 ° C.

  In this invention, by measuring the temperature in the combustion chamber using a radiation thermometer provided in the secondary combustion chamber, the combustion state is measured, and when the combustion state is more severe than the preset reference state, the front side Increase both the amount of recirculated exhaust gas and the amount of recirculated exhaust gas from the rear side. If the combustion state is milder than the reference state, reduce both the amount of recirculated exhaust gas from the front side and the amount of recirculated exhaust gas from the rear side. Is more preferable.

  By using an infrared camera, the surface temperature of the combustible layer can be measured, and the distribution ratio between the recirculated exhaust gas from the front side and the recirculated exhaust gas from the rear side is determined by the combustion position (combustion start position and (Or burnout position). In addition, by using a radiation thermometer, it is possible to measure the temperature in the combustion chamber, that is, the combustion state of the combusted material. If the combustion state is more severe than the reference state, the amount of recirculated exhaust gas from the front side and the rear side When the amount of recirculated exhaust gas from the engine is increased and the combustion state is milder than the reference state, the NOx concentration can be reduced by reducing both the amount of recirculated exhaust gas from the front side and the amount of recirculated exhaust gas from the rear side. Can be significantly reduced, and moreover, control capable of preventing an increase in CO concentration can be performed with higher accuracy.

  When incinerating when the combustible is municipal waste, it is difficult to adjust the combustion start position etc. by controlling the supply of recirculated exhaust gas because the combustion start position and burnout position fluctuate. Therefore, when it is necessary to change the combustion start position and the burnout position, it is preferable to change the position by operating at least one of the dust supply amount and the grate speed.

  When changing the combustion start position and the burn-out position, if both the combustion start position and the burn-out position are on the front side of the reference range, the amount of dust supply should be adjusted so that at least one is on the rear side of the reference range. It is preferable to perform at least one of a reduction and an increase in the grate speed of the drying stage.

  As for the combustion start position and the burnout position, when both are in front of the reference range, it is difficult to achieve both CO and NOx reduction. Simultaneously reduce CO and NOx by changing the distribution ratio and moving the combustion start position and burnout position to the side where it is easy to achieve both CO and NOx reduction (at least one is behind the reference range). More favorable control for the can be performed.

  According to the recirculation exhaust gas supply control method and stoker furnace of the stoker furnace of the present invention, by performing different control between when the combustion start position is at the front and when the combustion start position is at the reference range and the rear, Compared with the case where the control is not divided, the NOx concentration can be greatly reduced, and the CO concentration can be prevented from increasing.

FIG. 1 is a diagram showing an embodiment of a stoker furnace according to the present invention. FIG. 2 is a block diagram showing a main part of the control device for the stoker furnace. FIG. 3 is a diagram illustrating an example of a control result in the stoker furnace, where (a) is an example when proper control is performed, and (b) is an example when proper control is not performed. Respectively. FIG. 4 is a diagram showing an appropriate control state in three cases where combustion start positions are different and in each case in the stoker furnace according to the present invention. (A) shows the case where the combustion start position is closer to the front, (b) shows the case where the combustion start position is within the reference range, and (c) shows the case where the combustion start position is closer to the rear. . FIG. 5 is a diagram showing the flow of combustion exhaust gas when the distribution ratio of the recirculation exhaust gas from the front side and the recirculation exhaust gas from the rear side is changed when the combustion position is at the front, (a) 1 shows an example when proper control is not performed, and FIG. 4B shows an example when proper control is performed. FIG. 6a shows a case where the combustion position is closer to the front in a diagram showing a change in the state of dust on each grate when the combustion positions are different. FIG. 6 b shows a case where the combustion position is within the reference range in the diagram showing the change in the state of the dust on each grate when the combustion position is different. FIG. 6c shows a case where the combustion position is located rearward among the diagrams showing changes in the state of dust on each grate when the combustion positions are different. FIG. 6d shows a case where the combustion position is in a wide area in the diagram showing the change in the state of the dust on each grate when the combustion position is different.

  Embodiments of the present invention will be described below with reference to the drawings. In the following description, the left side of FIG. 1 is the front side, and the right side of FIG. 1 is the rear side.

  FIG. 1 schematically shows an embodiment of a stoker furnace according to the invention. The stoker furnace (1) is for incineration of garbage such as municipal waste.The lower primary combustion chamber (2) to which primary air is supplied and the upper secondary combustion chamber (2) to which secondary air is supplied ( 3) is connected to the style.

  A plurality of grate (4a) (4b) (4c) (4d) is installed at the bottom of the primary combustion chamber (2). The plurality of grate (4a) (4b) (4c) (4d) is a part of the drying stage grate (4a) that is on the front side and dries the waste by heat in the furnace, and the drying stage grate (4a) The first combustion stage grate (4b) and the second combustion stage grate (4c), which are the rear side and where the dry waste is ignited and mainly burned, and the combustion stage grate (4b) ( It is divided into a rear combustion stage grate (4d), which is a part on the rear side of 4c) that completely burns the unburned residue.

  Each grate (4a) (4b) (4c) (4d) is moved in the front-rear direction by the grate drive means (5), thereby moving the dust to the downstream side.

  The primary combustion chamber (2) has a front wall (11), a front ceiling wall (12), a rear wall (13) and a rear ceiling wall (14), and the front ceiling wall (12) and The opening between the rear ceiling wall (14) serves as an entrance to the secondary combustion chamber (3). The front ceiling wall (12) is located above the dry stage grate (4a).

  The front wall (11) of the primary combustion chamber (2) has a charging hopper (6) into which waste to be incinerated is put, and a pusher (dust supply device) that supplies the dust onto the drying grate (4a) ( And 7).

  Combustion primary air is supplied to each grate (4a), (4b), (4c) and (4d) by an air supply device (8) having a blower (8a). Secondary air is supplied to the secondary combustion chamber (3) by the secondary air supply nozzle (9).

  Recirculated exhaust gas (abbreviated as “EGR” in FIG. 1) is supplied into the primary combustion chamber (2) by the recirculated exhaust gas supply device (10). The front ceiling wall (12) is provided with a plurality of nozzles (10a) that supply recirculated exhaust gas from the front side, and the rear wall (13) is a nozzle (10b) that supplies recirculated exhaust gas from the rear side. ) Are provided at a plurality of locations. By these nozzles (10a) and (10b), the recirculated exhaust gas discharged from the secondary combustion chamber (3) is supplied into the primary combustion chamber (2) in the direction of the arrow.

  The supply direction of the recirculated exhaust gas from the front ceiling wall (12) is preferably 15 ° downward to 15 ° upward with respect to the horizontal direction, and the supply direction of the recirculated exhaust gas from the rear wall (13) is horizontal to horizontal. 20 ° upward with respect to the direction is preferred. In order to supply the recirculated exhaust gas from the rear side, it may be supplied from the rear ceiling wall (14) instead of the rear wall (13).

  The amount of dust supplied to the drying stage grate (4a) by the pusher (7), the grate (4a) (4b) (4c) (4d) of each grate moved by the grate driving means (5) The moving speed, the amount of primary air supplied to the primary combustion chamber (2) by the air supply device (8), the amount of recirculated exhaust gas supplied from the front ceiling wall (12) and the rear wall (13), etc. It is controlled by the control device (20) shown in FIG.

  An infrared camera (temperature distribution) that measures the temperature distribution in the primary combustion chamber (2) is located on the rear ceiling wall (14) above the primary combustion chamber (2) and above the rear combustion grate (4d). (Measuring device) (15) is provided.

  A radiation thermometer (pyrometer) (16) for measuring the temperature in the combustion chamber is provided in the secondary combustion chamber (3). According to the radiation thermometer (16), the temperature in the combustion chamber can be measured, and thereby the combustion state (flame state) of the waste can be determined.

  When recirculated exhaust gas is supplied into the primary combustion chamber (2) from the front ceiling wall (12) and the rear wall (13), the combustion exhaust gas from the dust layer is transferred to the front ceiling wall (12) side and the rear wall (13) side. Thus, the entire primary combustion chamber (2) is effectively utilized as a combustion space. The combustion exhaust gas drawn to the front ceiling wall (12) side mainly contains NOx precursor (NH3) and combustible gas. The flue gas drawn toward the rear wall (13) mainly contains combustible gas (CO) and oxygen generated from fixed carbon and does not contain much NOx precursor. For this reason, on the rear wall (13) side, CO can be sufficiently burned in the state where the NOx precursor is not present. Therefore, the combustion exhaust gas attracted to the front ceiling wall (12) side and the combustion exhaust gas attracted to the rear wall (13) side are mixed in the secondary combustion chamber (3), and the temperature rise is mitigated even if the combustion occurs. Thereby, the amount of NOx can be reduced.

  When the influence of the recirculated exhaust gas jet from the front side is relatively strong, the NOx precursor and the combustible gas concentrate on the front wall (11) side. As a result, the NOx precursor at the inlet of the secondary combustion chamber (3) As the temperature increases and the temperature of the secondary combustion chamber (3) rises, the amount of NOx generated increases. On the contrary, when the influence of the recirculated exhaust gas jet from the rear side is relatively strong, the NOx precursor flows in the rear wall (13) side, and the NOx precursor in the atmosphere heated by the combustion of fixed carbon. Changes to NOx, and as a result, the amount of generated NOx also increases in this case.

  Therefore, it is possible to reduce the amount of NOx generated by appropriately controlling the supply amounts of the recirculated exhaust gas from the front side and the recirculated exhaust gas from the rear side.

In order to optimize the amount of recirculated exhaust gas from the front side and recirculated exhaust gas from the rear side, the main points obtained by thermofluid analysis using general-purpose software Fluent Ver.6.3 are shown in FIGS. And in Table 1.

  In Table 1, η means combustion efficiency and is obtained by the following equation.

η = 1−ΔHnFn / HIFI
ΔHn: lower calorific value [kJ / kg] of unburned combustible at the outlet of the primary combustion chamber, Fn: mass flow rate [kg / h] of passing gas at the outlet of the primary combustion chamber, HI: lower calorific value [kJ of the inflowable combustible] / Kg], FI: mass flow rate [kg / h] of inflow combustible component.

  FIG. 3 (a) shows an example in the case where proper control is performed. The low NOx and low COx concentration is 0.6 ppm at the outlet of the secondary combustion chamber (3) and the NOx concentration is 16 ppm at the furnace outlet. CO combustion is realized.

  FIG. 3B shows an example in a case where proper control is not performed (the influence of the jet of recirculated exhaust gas from the rear side is strong). The temperature distribution in FIG. 3 (b) shows that the temperature of the combustion exhaust gas entering the secondary combustion chamber (3) from the rear side of the primary combustion chamber (2) is higher than that in FIG. The CO concentration at the outlet of the combustion chamber (3) is 0.3 ppm and the NOx concentration at the furnace outlet is 35 ppm, which has the problem of low CO but high NOx.

  In FIG. 4, (b) shows a state in which combustion within the reference range is performed, and the distribution ratio between the recirculated exhaust gas from the front side and the recirculated exhaust gas from the rear side is represented by the front side 45 / rear side 55. Thus, low NOx and low CO combustion with a NOx amount of 9 ppm and a CO amount of 0.1 ppm is realized (see the combustion position “reference range” in Table 1). The recirculated exhaust gas ratio is 30.4% with respect to the exhaust gas at the furnace outlet, the primary air ratio is set to 0.89, and the secondary air ratio is set to 0.15.

  FIGS. 4A and 4C show an appropriate control state when the combustion positions (combustion start position and burnout position) are different. The combustion start position is closer to the front side in (a) than in (b) within the reference range, and closer to the rear side in (c). Within range and back can be distinguished. In the case of the front shown in FIG. 4A, the NOx amount is 7 ppm and the CO concentration is 2.4 ppm (see the distribution ratio 35/65 of the combustion position “front” in Table 1), as shown in FIG. 4C. In the case of the rear side, the NOx amount is 8 ppm and the CO concentration is 0.2 ppm (see the combustion position “rear side” in Table 1).

  In FIG. 5, (a) shows the case where the combustion position is in the front and the distribution ratio is the front side 50 / rear side 50, and (b) shows the distribution ratio in the case where the combustion position is the front side and the distribution ratio is 35 / rear For the case of the side 65, the respective combustion gas streamlines are shown. According to FIG. 5 (a), when the distribution ratio is the front side 50 / rear side 50, the recirculated exhaust gas from the front side is relatively larger than the appropriate condition, and the combustion gas is strongly attracted to the front side. As a result, the combustion efficiency at the outlet of the primary combustion chamber (2) is low, and the CO concentration and NH3 concentration at the outlet of the secondary combustion chamber (3) are high (distribution ratio 50/50 at the combustion position “front” in Table 1). See). On the other hand, according to FIG. 5 (b), the distribution ratio is set to the front side 35 / rear side 65, which is an appropriate condition, and the combustion gas is less likely to be drawn to the front side. As a result, the primary combustion chamber ( 2) The combustion efficiency at the outlet is improved, and the CO concentration and NH3 concentration at the secondary combustion chamber (3) outlet are low (see the distribution ratio 35/65 of the combustion position “front” in Table 1).

  FIGS. 6a to 6d show changes in the state of dust on each grate when the combustion positions are different. 6a corresponds to the front, FIG. 6b corresponds to the reference range, FIG. 6c corresponds to the rear, and FIG. 6d corresponds to the wide area. 6a to 6d, each grate (4a) (4b) (4c) (4d) is composed of 7, 8, 8 and 9 grate blocks, respectively, up to the 32nd grate. There are blocks. From the left, the three curves shown in each figure show the moisture abundance in the garbage, the volatile content (pyrolysis gas) abundance in the garbage, and the fixed carbon abundance in the garbage, respectively. When the combustion positions are classified, the state where the pyrolysis gas generation region in FIG. Then, for example, as shown in FIG. 6a, the case where the pyrolysis gas generation start position, that is, the combustion start position is located before the seventh block is defined as “frontward”, and as shown in FIG. The case where the combustion start position is at the 10th block position is defined as “within reference range”, and the case where the combustion start position is located after the 10th block is defined as “rearward” as shown in FIG. To do. Usually, the burnout position moves back and forth depending on the combustion start position, so that the case classification may be performed using the combustion start position, or may be performed using the burnout position. In addition to the cases of “frontward”, “within the reference range”, and “rearward”, as shown in FIG. 6d, the combustion start position may be frontward and the burnout position may be rearward. It is more preferable to set the “wide area” to be a control different from the other three cases.

  The strength of the recirculated exhaust gas jet is determined by the combustion position (combustion start position and / or burnout position) and combustion state (flame position and flame state) of the dust on the grate (4a) (4b) (4c) (4d) Depends on. That is, depending on the combustion position and combustion state of the dust on the grate (4a) (4b) (4c) (4d), the recirculated exhaust gas from the front and the recirculation from the rear supplied to the primary combustion chamber (2) It is necessary to control the exhaust gas. In the control, as shown in FIGS. 6a to 6d, it is preferable to divide the case based on whether the combustion start position and / or the burnout position is the front, the reference range, the rear, or the wide area. .

  As shown in FIG. 4, when the combustion position is closer to the front, it is preferable to reduce the amount of recirculated exhaust gas from the front side and increase the amount of recirculated exhaust gas from the rear side. Further, when the combustion position is at the rear side, control may be performed so that the amount of recirculated exhaust gas from the front side is increased and the amount of recirculated exhaust gas from the rear side is decreased. When the combustion position is at the rear side, the same control as that in the reference range may be used.

  As shown in FIG. 2, the control device (20) includes a combustion position calculation unit (21) for calculating a combustion position by obtaining a temperature distribution in the primary combustion chamber (2) from output data of the infrared camera (15), A combustion state calculation unit (22) that calculates the combustion state from the output data of the radiation thermometer (16), a dust supply amount control unit (23) that controls the amount of dust supplied to the drying stage grate (4a), and Grate speed control unit (24) for controlling the moving speed of the grate (4a) (4b) (4c) (4d), an air supply rate control unit (25) for controlling the air supply rate, and a recirculated exhaust gas And a recirculation exhaust gas control section (26) for controlling the supply amount of the exhaust gas.

  The combustion position calculation unit (21) calculates the temperature in the primary combustion chamber (2) based on the output of the infrared camera (15), and the reference range for the combustion position (combustion start position and / or burnout position). In this case, the information is classified into any one of the front, the rear, and the wide area, and the divided information is output to the recirculation exhaust gas control unit (26).

  In order to obtain the combustion start position and the burnout position, for example, as described in Japanese Patent No. 3916450, the imaging data of the infrared camera (15) is processed into temperature distribution data having a higher temperature as the color becomes darker. 6) The position where the area above the predetermined temperature (combustion start temperature) is a predetermined value when viewed from the side is determined as the combustion start position, and the area above the predetermined temperature (burn-out temperature) when viewed from the ash outlet (17) What is necessary is just to obtain | require the position where becomes a predetermined value as a burnout position.

  The recirculation exhaust gas control unit (26) obtains an appropriate distribution ratio between the recirculation exhaust gas from the front side and the recirculation exhaust gas from the rear side, and supplies the recirculation exhaust gas supply device (10) to this distribution ratio. The distribution ratio control unit (27) that issues a command, and the recirculation exhaust gas supply device (10) to obtain the appropriate supply amount of the recirculation exhaust gas from the front side and the recirculation exhaust gas from the rear side, and to obtain this supply amount A supply amount control unit (28) for issuing a command to

  From the combustion position calculation unit (21) to the distribution ratio control unit (27) of the recirculation exhaust gas control unit (26), the combustion range (combustion start position and / or burnout position) is set to the reference range, front side, rear side. And the classification information for either of the wide area is sent. The distribution ratio control unit (27) obtains the distribution ratio of the recirculated exhaust gas according to the table accumulated in advance, and controls the distribution ratio of the recirculated exhaust gas based on this.

  As described above, if the combustion position is within the reference range, the control content is not changed and the control at A / B that is the reference distribution ratio is continued. And when the combustion position is in front, the recirculated exhaust gas amount from the front side is lowered by a predetermined amount α (> 0), the recirculated exhaust gas amount from the rear side is increased by the same amount α, and the distribution ratio is increased. (A−α) / (B + α). In addition, when the combustion position is at the rear, the recirculated exhaust gas amount from the front side is increased by a predetermined amount β (≧ 0), and the recirculated exhaust gas amount from the rear side is decreased by the same amount β to increase the distribution ratio. It is assumed that (A + β) / (B−β). When the combustion position is wide, the amount of recirculated exhaust gas from the front side is decreased by a predetermined amount γ (≧ 0), and the amount of recirculated exhaust gas from the rear side is increased by the same amount γ, so that the distribution ratio is (A −γ) / (B + γ).

  On the other hand, the supply amount control unit (28) of the recirculation exhaust gas control unit (26) is within the range in which the measurement value by the radiation thermometer (16) is set in advance for the combustion state from the combustion state calculation unit (22). Information that is either a reference condition, more severe than the reference and milder than the reference is sent. In the supply amount control unit (28), the supply amount of the recirculated exhaust gas is obtained according to the table accumulated in advance, and the recirculated exhaust gas supply amount is controlled based on this.

  As for the control content, if the combustion state of the waste is in the reference state, the control at A / B that is the reference distribution ratio is continued without being changed. When the waste combustion state is more severe than the preset reference state, the amount of recirculated exhaust gas from the front side and the amount of recirculated exhaust gas from the rear side are both multiplied by δ (> 1), and the entire supply amount Increase. When the waste combustion state is milder than the reference state, the amount of recirculated exhaust gas from the front side and the amount of recirculated exhaust gas from the rear side are both multiplied by ε (<1) to reduce the entire supply amount.

  The combustion position calculation unit (22) further instructs the feed amount control unit (23) to reduce the feed amount when the obtained case classification is the front side, and the grate speed control unit (24 ) To increase the moving speed of the drying grate (4a). As a result, the combustion position moves to the rear side (the direction within the reference range).

  Thus, according to the stoker furnace (1) equipped with the control device (20), the combustion position and combustion state of the waste are measured and quantified, and based on this value, the amount of recirculated exhaust gas from the front side and the rear side By controlling the amount of recirculated exhaust gas, the NOx concentration at the furnace outlet can be greatly reduced without increasing the CO concentration at the outlet of the secondary combustion chamber (3).

(1) Stoker furnace
(2) Primary combustion chamber
(3) Secondary combustion chamber
(4a) (4b) (4c) (4d) grate
(6) Loading hopper
(10) Recirculation exhaust gas supply device
(11) Front wall
(12) Front ceiling wall
(13) Rear wall
(14) Rear ceiling wall
(15) Infrared camera (temperature distribution measuring device)
(16) Radiation thermometer
(20) Control device
(21) Combustion position calculator
(22) Combustion state calculator
(23) Dust supply control unit
(24) Grate speed controller
(26) Recirculation exhaust gas control unit

Claims (14)

The primary combustion chamber includes a lower primary combustion chamber to which primary air is supplied, an upper secondary combustion chamber to which secondary air is supplied, and a plurality of grate installed at the bottom of the primary combustion chamber. Controls the supply of recirculated exhaust gas in a stoker furnace that has a front wall, a front ceiling wall, a rear wall, and a rear ceiling wall provided with a charging hopper and that supplies recirculated exhaust gas into the primary combustion chamber A way to
The recirculated exhaust gas from the front side is supplied from the front ceiling wall to the rear, the recirculated exhaust gas from the rear side is supplied from the rear wall or the rear ceiling wall to the front, and the temperature distribution in the primary combustion chamber is measured. Then, for at least one of the combustion start position and the burnout position on the grate, the position in the front-rear direction with respect to a preset reference range is determined, and at least one of the combustion start position and the burnout position is There are at least three cases: the front side, the rear side and the reference range compared to the reference range, and the recirculated exhaust gas from the front side and the recirculation from the rear side according to each case A recirculation exhaust gas supply control method for a stoker furnace, characterized by changing a distribution ratio with exhaust gas.   When the combustion start position is closer to the reference range, the amount of recirculated exhaust gas from the front side is decreased and the amount of recirculated exhaust gas from the rear side is increased, and the combustion start position is closer to the reference range. 2. The recirculation exhaust gas supply control method for a stoker furnace according to claim 1, wherein the control is performed to increase the recirculation exhaust gas amount from the front side and to decrease the recirculation exhaust gas amount from the rear side.   When the combustion start position is in front of the reference range, it is further divided into cases where the burnout position is in front of and in the rear of the reference range. The recirculation exhaust gas supply control method for a stoker furnace according to claim 1 or 2, wherein a distribution ratio of the recirculation exhaust gas from the rear and the recirculation exhaust gas from the rear side is changed.   The recirculation exhaust gas supply control method for a stoker furnace according to any one of claims 1 to 3, wherein the temperature distribution in the primary combustion chamber is measured by an infrared camera.   By measuring the temperature in the combustion chamber using a radiation thermometer provided in the secondary combustion chamber, the combustion state is measured. If the combustion state is more severe than the preset reference state, the recirculated exhaust gas from the front side The amount of recirculated exhaust gas from the front side and the amount of recirculated exhaust gas from the rear side are both lowered when the combustion amount is higher than the reference state. The recirculated exhaust gas supply control method for a stoker furnace according to any one of claims 1 to 4.   6. The method according to claim 1, wherein at least one of a dust supply amount and a grate speed is changed to move at least one of a combustion start position and a burnout position on the grate. Recirculation exhaust gas supply control method for stoker furnace.   If both the combustion start position and the burnout position are on the front side of the reference range, at least a decrease in the amount of feed and an increase in the grate speed of the drying stage so that at least one of them is behind the reference range. The recirculation exhaust gas supply control method for a stoker furnace according to claim 6, wherein one of them is executed. The primary combustion chamber includes a lower primary combustion chamber to which primary air is supplied, an upper secondary combustion chamber to which secondary air is supplied, and a plurality of grate installed at the bottom of the primary combustion chamber. Is a stoker furnace having a front wall, a front ceiling wall, a rear wall and a rear ceiling wall provided with a charging hopper, and supplying recirculated exhaust gas into the primary combustion chamber,
A recirculation exhaust gas supply device for supplying recirculation exhaust gas from the front side toward the rear from the front ceiling wall and a recirculation exhaust gas from the rear side toward the front from the rear wall or the rear ceiling wall; and a primary combustion chamber A temperature distribution measuring device for measuring the temperature distribution, and a control device for controlling combustion so as to reduce the CO concentration and the NOx concentration;
The control device obtains the temperature distribution in the primary combustion chamber from the output data of the temperature distribution measuring device and calculates at least one of the combustion start position and the burnout position, and a re-control for controlling the supply amount of the recirculated exhaust gas. A circulation exhaust gas control unit,
The recirculation exhaust gas control unit obtains a position in the front-rear direction with respect to a preset reference range for at least one of the combustion start position and the burnout position on the grate, and determines the combustion start position and the burnout position. When at least one of the positions is at the front of the reference range, at the back, or at the reference range, it is divided into at least three cases. A stoker furnace characterized by changing the distribution ratio with the recirculated exhaust gas from the side.   When the combustion start position is closer to the reference range, the recirculation exhaust gas control unit lowers the recirculation exhaust gas amount from the front side and increases the recirculation exhaust gas amount from the rear side, and the combustion start position is within the reference range. 9. The stoker furnace according to claim 8, wherein when it is further rearward, control is performed so that the amount of recirculated exhaust gas from the front side is increased and the amount of recirculated exhaust gas from the rear side is decreased.   When the combustion start position is in front of the reference range, the recirculation exhaust gas control unit further classifies the case in which the burnout position is in front of or behind the reference range. The recirculation exhaust gas supply control method for a stoker furnace according to claim 8 or 9, wherein the distribution ratio between the recirculation exhaust gas from the front side and the recirculation exhaust gas from the rear side is changed according to each case.   The stoker furnace according to any one of claims 8 to 10, wherein the temperature distribution measuring device is an infrared camera. A radiation thermometer that is provided in the secondary combustion chamber and measures the temperature in the combustion chamber; and the control device further includes a combustion state calculation unit that calculates a combustion state from output data of the radiation thermometer,
The recirculation exhaust gas control unit increases both the recirculation exhaust gas amount from the front side and the recirculation exhaust gas amount from the rear side when the combustion state is more severe than the preset reference state, and the combustion state is higher than the reference state. The stoker furnace according to any one of claims 8 to 11, wherein in a mild case, both the amount of recirculated exhaust gas from the front side and the amount of recirculated exhaust gas from the rear side are reduced.   The control device further includes a feed amount control unit that controls the amount of dust supplied to the drying stage grate, and a grate speed control unit that controls the moving speed of each grate, and starts combustion on the grate. The stoker furnace according to any one of claims 8 to 12, wherein at least one of a feed amount and a grate speed is changed in order to move at least one of the position and the burnout position.   When both the combustion start position and the burnout position are on the front side of the reference range, the control device reduces the amount of dust supplied by the dust supply amount control unit so that at least one is on the rear side of the reference range. The stoker furnace according to claim 13, wherein at least one of the increase of the grate speed of the drying stage by the grate speed control unit is executed.