JP6616153B2 - boiler - Google Patents

Description

  The present invention relates to a boiler having a combustion section for introducing a flame generated by a burner.

  As a boiler, for example, a can that stores water has a hollow combustion part such as a furnace tube and a plurality of smoke pipes connected to the combustion part, and a burner is attached to the combustion part. There is a known type of boiler (see, for example, Patent Document 1). In this type of boiler, a flame generated by burning fuel with a burner is introduced into the combustion section, and further, a combustion gas generated along with this flame is guided from the combustion section to each smoke pipe. Thereby, in a boiler, the heat which combustion gas has is heat-exchanged with the water stored in the can body via the wall surface of a combustion part, and the tube wall of each smoke pipe.

  Conventionally, fossil fuels have been used as fuel for burners provided in this type of boiler.

By the way, as one of the measures for reducing CO ₂ in the global warming problem, promotion of the use of renewable energy can be cited, and so-called woody biomass such as wood is being used as fuel.

  When using woody biomass as fuel, the woody biomass is pulverized by a pulverizer to form a powdery biomass fuel with an average particle size of about 100 μm, and combustion in a state suspended in an air stream (spatial combustion) ) Becomes possible. For this reason, the biomass fuel of the powder is used as a burner fuel.

  Therefore, the present inventors are considering applying a burner capable of using powdered biomass fuel as a burner for generating a flame to be introduced into the combustion section of the boiler.

JP-A-10-185111

  However, since woody biomass contains fibers, uniform pulverization is difficult, and even if pulverization is performed so that the average particle size is about 100 μm, the obtained powder contains space in the flame of the burner. Particles with large particle sizes that cannot be burned out by combustion may be mixed.

  Therefore, in a burner that uses powdered biomass fuel, if the fuel particles with large particle sizes as described above are mixed in the biomass fuel, the unburned portion of the fuel particles remains unburned. There is a possibility of being discharged from the burner along with the flame.

  Therefore, when the conventional fossil fuel burner for generating a flame to be introduced into the combustion section is simply replaced with a burner using powdered biomass fuel, the following problems may occur. Is done.

  That is, when unburned portion remaining fuel particles are discharged from a burner that uses powdered biomass fuel, the fuel particles enter the combustion section and fall to the inner bottom of the combustion section. However, since the conventional boiler is premised on the use of a burner that spatially burns fossil fuel, it is not assumed that the above fuel particles enter the combustion section. There is no special means for treating the fuel particles that fall.

  Therefore, in a boiler equipped with a burner that uses powdered biomass fuel in the combustion part, deposits of fuel particles remaining in the unburned part are formed on the inner bottom part of the combustion part as the operating time elapses.

  The boiler repeatedly operates and shuts down the burner according to the demand for steam and hot water, but the fuel particle deposits that form on the inner bottom of the combustion section may spill when the burner is shut down. If such deposits are struck, it causes smoke and odor emission from the boiler. In addition, when the amount of deposits at the inner bottom portion of the combustion section increases, unexpected combustion of the deposits may occur abruptly when the operation of the burner is resumed, possibly causing abnormal combustion with incomplete combustion.

  Therefore, the present invention can use powdery biomass fuel as a burner fuel for generating a flame to be introduced into the combustion section, and deposits due to fuel particles remaining in the unburned portion at the inner bottom of the combustion section. It is an object of the present invention to provide a boiler that can prevent the occurrence of the above.

In order to solve the above-mentioned problem, the present invention provides a can body in which water is stored, a combustion part disposed in a lower part of the can body, and a vertically extending direction in the can body so as to be disposed in the combustion part. In a boiler comprising a plurality of connected smoke pipes and a burner attached to the combustion section, the burner includes a combustion chamber for generating a flame by combustion of powdered biomass fuel, A pulverized fuel supply pipe for supplying pulverized biomass fuel is connected to one end side in the axial direction, and the other end side in the axial direction of the combustion chamber is a flame outlet that blows the flame and combustion gas into the combustion section. It is, wherein the combustion section comprises a combustion unit of the flame are entrained in the flame ejected from the ejection port and fuel particles which fall to the inner bottom portion of the combustion section is discharged from the flame jet port of the burner, each The smoke pipe is blown into the combustion section The combustion gases to a boiler having a configuration for collection at the top of the can body which communicates with the outside of the can body.

The combustion section includes an air supply pipe that blows combustion air obliquely downward toward the inner bottom of the combustion section, and the arrangement position of the air supply pipe in the combustion section in the vertical direction is the flame in the combustion section. It is above the arrangement position of the jet port in the vertical direction, and the combustion means is constituted by the air supply pipe.

The combustion means has a function of introducing a flame from a flame outlet of the burner into the combustion part obliquely downward toward the inner bottom part of the combustion part, and a vertical arrangement position of the combustion means in the combustion part is as Ru upward der structure than the vertical arrangement positions of the flame vent in the combustion section.

  The burner has a configuration in which the flame outlet is bent obliquely downward, and the combustion means has a configuration in which the burner having the configuration is attached to the combustion section.

  The burner is inclined so that the flame outlet is inclined downward, and the combustion means is configured such that the burner in the attitude is attached to the combustion section.

  According to the boiler of the present invention, powdery biomass fuel can be used as the burner fuel for generating a flame to be introduced into the combustion section, and the unburned portion remains on the inner bottom of the combustion section. The generation of deposits can be prevented.

It is a general | schematic cutting side view of the boiler of 1st Embodiment. It is a general | schematic cutting side view of the boiler of 2nd Embodiment. It is a general | schematic cutting side view of the boiler of 3rd Embodiment.

  The boiler of the present invention will be described below with reference to the drawings.

[First Embodiment]
FIG. 1 is a schematic cut side view showing the boiler 1 of the first embodiment.

  The boiler 1 of the present embodiment includes a can body 2 in which water 3 to be heated is stored, a combustion section 4 disposed in the can body 2, a plurality of smoke pipes 6, and a combustion gas collecting section 7, and further combusts. The burner 5 attached to the part 4 and the combustion means 8 for the fuel particles 10 a that have fallen to the inner bottom part of the combustion part 4 are provided. In FIG. 1, for convenience of illustration, the water 3 is hatched with dots.

  In the present embodiment, for example, the can body 2 has a cylindrical shape extending vertically, the combustion section 4 is disposed at the lower portion of the can body 2, the combustion gas collecting section 7 is disposed at the upper portion of the can body 2, and a plurality of smoke pipes Reference numeral 6 denotes a configuration arranged between the combustion unit 4 and the combustion gas collecting unit 7.

  The combustion part 4 is provided with a ceiling wall part 4a, a bottom wall part 4b, and a side wall part 4c, and a space part is formed therein.

  The combustion unit 4 has a cylindrical shape with a smaller diameter than the inner diameter of the can body 2. The ceiling wall portion 4 a projects outward from the outer peripheral surface of the side wall portion 4 c, and the outer peripheral surface of the ceiling wall portion 4 a is connected to the inner surface of the side wall of the can body 2. Holes 4d are provided at a plurality of locations in the circumferential direction on the protruding outer peripheral edge of the ceiling wall 4a, and water 3 can pass through the holes 4d in the vertical direction of the ceiling wall 4a.

  A horizontal tubular member 9 is provided between one place in the circumferential direction of the side wall portion 4c and the side wall of the can body 2 located on the outer peripheral side thereof. One end side (right end side in FIG. 1) of the cylindrical member 9 located near the center of the can body 2 is attached to the side wall portion 4c so as to communicate with the internal space of the combustion portion 4. The other end side (left end side in FIG. 1) of the cylindrical member 9 is attached so as to penetrate the side wall of the can body 2.

  A flame outlet 5 c of the burner 5 is inserted into the tubular member 9 from the outside of the can body 2. In this state, the burner 5 is attached to the tubular member 9 or the can body 2 via attachment means (not shown). This attachment means is preferably of a type that allows the burner 5 to be removed as needed, such as during replacement of the burner 5 or during maintenance.

  The burner 5 has a cylindrical combustion chamber 5a inside. One end side (left end side in FIG. 1) of the combustion chamber 5a in the axial direction is closed by an end wall 5b, and the other end side (right end side in FIG. 1) in the axial direction is opened to form a flame jet 5c. Yes.

  Further, the burner 5 includes an air supply pipe 12a for supplying combustion air 11 to the combustion chamber 5a, a pulverized fuel supply pipe 13 for supplying pulverized biomass fuel 10 to the combustion chamber 5a, and an ignition (not shown). And means.

  As the powder biomass fuel 10, for example, a powder biomass fuel 10 obtained by pulverizing wood biomass so as to have an average particle size of about 100 μm is used. In addition, the conveyance of the pulverized biomass fuel 10 in the pulverized fuel supply pipe 13 may be performed by air conveyance using conveyance air.

  Thereby, in the combustion chamber 5a, the pulverized biomass fuel 10 supplied from the pulverized fuel supply pipe 13 can be burned by the combustion air 11 supplied from the air supply pipe 12a to generate a flame. Therefore, the burner 5 can eject the flame generated by the combustion of the powdered biomass fuel 10 from the flame outlet 5c. Therefore, in the boiler 1 of the present embodiment, the flame ejected from the flame ejection port 5 c of the burner 5 inserted into the tubular member 9 is blown sideways into the combustion unit 4 together with the combustion gas 14.

  If the powder biomass fuel 10 burned by the burner 5 is mixed with fuel particles having a large particle size (hereinafter simply referred to as large particle fuel particles) that cannot be burned out by space combustion in a flame, Large-sized fuel particles may be discharged from the flame ejection port 5c along with the flame with the unburned portion remaining. Thus, when the fuel particle 10a with which an unburned part remains is discharged | emitted from the flame outlet 5c, the fuel particle 10a falls to the inner bottom part of the combustion part 4, as shown in FIG. Hereinafter, the fuel particles 10a in which the unburned portion remains are simply referred to as fuel particles 10a.

  The combustion means 8 is for applying heat to the fuel particles 10a falling on the inner bottom portion of the combustion section 4 as described above in an atmosphere in which oxygen is present to ignite and burn the fuel particles 10a. .

  In the present embodiment, for example, an air supply pipe 12b is provided at a position facing the opening on one end side of the cylindrical member 9 in the combustion section 4, that is, a position facing the flame jet port 5c of the burner 5, and this air supply is provided. The combustion means 8 is comprised by the pipe | tube 12b.

  The air supply pipe 12 b is attached to the side wall of the can body 2 so as to penetrate in the inner and outer directions, and the tip end side thereof is connected to open to the side wall part 4 c of the combustion unit 4. The front end side of the air supply pipe 12b is arranged in an obliquely downward angle posture so that the combustion air 11 blown into the combustion section 4 from the air supply pipe 12b flows toward the inner bottom of the combustion section 4. is there.

  Thereby, the combustion means 8 can blow the combustion air 11 into the combustion part 4 diagonally downward from the air supply pipe 12b. Therefore, the high-temperature combustion gas 14 that is blown sideways into the combustion unit 4 from the flame outlet 5 c of the burner 5 and led to the vicinity of the air supply pipe 12 b is entrained in the obliquely downward flow of the combustion air 11. Can be sent toward the inner bottom surface of the combustion section 4. For this reason, the combustion means 8 can supply the heat of the combustion gas 14 and the oxygen contained in the combustion air 11 to the fuel particles 10a falling on the inner bottom portion of the combustion section 4. Thus, the fuel particles 10a can be ignited and burned.

  For the air supply pipe 12b, the air supply to the combustion unit 4 depends on the planar shape of the combustion unit 4 and the dispersion state when the fuel particles 10a discharged from the burner 5 fall on the inner bottom of the combustion unit 4. Of course, the arrangement and the number of tubes 12b may be determined arbitrarily.

  A blower 15 is connected to the upstream side of the air supply pipe 12 a of the burner 5 and the air supply pipe 12 b of the combustion means 8 via a combustion air line 16. The combustion air line 16 is provided with flow rate adjusting valves 17a and 17b for individually adjusting the flow rate of the combustion air 11 supplied to the air supply pipe 12a and the air supply pipe 12b.

  The plurality of smoke pipes 6 are arranged in parallel between the combustion unit 4 and the combustion gas collecting unit 7 so as to extend in the vertical direction. The lower end side of each smoke pipe 6 is attached to the ceiling wall portion 4 a in a state communicating with the internal space of the combustion portion 4. Thereby, the ceiling wall part 4a becomes a header of the lower end side of each smoke pipe 6, and the combustion gas 14 in the combustion part 4 flows into each smoke pipe 6 in a dispersed manner.

  On the other hand, the upper end side of each smoke pipe 6 is attached to the bottom wall portion 7 a of the combustion gas collecting portion 7 in a state of communicating with the internal space of the combustion gas collecting portion 7. As a result, the bottom wall portion 7 a becomes a header on the upper end side of each smoke pipe 6, and the combustion gas 14 circulated in each smoke pipe 6 then enters the combustion gas collecting section 7 and collects.

  The combustion gas collecting part 7 has a hollow cylindrical shape having a smaller diameter than the inner diameter of the can body 2. The bottom wall portion 7 a of the combustion gas collecting portion 7 projects outward from the outer peripheral surface of the side wall portion 7 b of the combustion gas collecting portion 7, and the outer peripheral surface of the bottom wall portion 7 a is connected to the inner surface of the side wall of the can body 2. ing. The outer peripheral edge of the bottom wall 7a is provided with holes 7c at a plurality of locations in the circumferential direction, and water 3 can pass through the hole 7c in the vertical direction of the bottom wall 7a.

  One end side (the left end side in FIG. 1) of the combustion gas discharge duct 18 attached so as to penetrate the side wall of the can body 2 on the outer peripheral side in the inner and outer direction is burned at one place in the circumferential direction of the side wall portion 7b. It is attached so as to communicate with the internal space of the gas collecting portion 7. Thereby, the combustion gas 14 collected in the combustion gas collecting part 7 can be discharged from the combustion gas collecting part 7 to the outside of the can body 2 as the exhaust gas 20 through the combustion gas discharge duct 18.

  A cyclone 19 for exhaust gas treatment is connected to the other end side (the right end side in FIG. 1) of the combustion gas discharge duct 18 on the downstream side in the exhaust gas distribution direction. Thereby, the exhaust gas 20 discharged through the combustion gas discharge duct 18 can separate the soot 21 by the cyclone 19. The exhaust gas 20 and the dust 21 discharged from the cyclone 19 may be sent to a processing unit (not shown) and appropriately processed.

  The combustion part 4, the smoke pipe 6 and the combustion gas collecting part 7 are supported on the can 2 via the tubular member 9, the combustion gas discharge duct 18, the ceiling wall part 4 a and the bottom wall part 7 a. 4, the smoke pipe 6 and the weight of the combustion gas collecting portion 7 are transmitted to and supported by the can body 2 mainly through the ceiling wall portion 4a and the bottom wall portion 7a.

  In addition, 22 is a means for supplying water into the can body 2. Moreover, although not shown in figure, the boiler 1 of this embodiment is equipped with the means for absorbing the change of the dimension accompanying the temperature change of each part, and preventing an excessive stress concentration from arising.

  When operating the boiler 1 of this embodiment, supply of the pulverized biomass fuel 10 from the pulverized fuel supply pipe 13 and supply of the combustion air 11 from the air supply pipe 12a to the combustion chamber 5a of the burner 5 are performed. The flame generated by the combustion of the powdered biomass fuel 10 is introduced into the combustion unit 4 from the flame outlet 5c. Thereby, the combustion gas 14 blown together with the flame from the burner 5 enters the respective smoke pipes 6 from the combustion unit 4 and flows in the direction of the combustion gas collecting unit 7.

  Therefore, in the boiler 1 of the present embodiment, the heat held by the combustion gas 14 is exchanged with the water 3 stored in the can 2 via the wall surfaces of the combustion unit 4 and the tube walls of the smoke pipes 6. The water 3 can be heated.

  The heating of the water 3 may be performed so that hot water having a set temperature is generated when the boiler 1 of the present embodiment is applied to a hot water boiler. Moreover, what is necessary is just to make it heat the water 3 so that the steam of the set pressure may generate | occur | produce when the boiler 1 of this embodiment is applied to a steam boiler. The hot water and steam generated in this way may be supplied to the customer through a supply means (not shown) connected to the can body 2.

  During operation of the boiler 1 of the present embodiment, when large particle fuel particles are mixed in the powdered biomass fuel 10 supplied to the burner 5, the fuel particles 10a are discharged from the flame outlet 5c to the combustion unit 4. May fall to the inner bottom of the combustion section 4.

  In this case, the burner 5 of the present embodiment is provided with the combustion means 8, and the combustion air 11 blown obliquely downward from the air supply pipe 12 b into the combustion unit 4, and the high-temperature combustion gas 14 is entrained in the combustion unit 4. Since the fuel particles 10a are sent toward the bottom surface, the fuel particles 10a can be burned by supplying heat and oxygen necessary for ignition to the fuel particles 10a falling to the inner bottom portion of the combustion section 4. As a result, the fuel particles 10a falling on the inner bottom portion of the combustion section 4 are burned out sequentially.

  Thus, according to the boiler 1 of this embodiment, the pulverized biomass fuel 10 can be used as the fuel of the burner 5 for generating the flame introduced into the combustion unit 4. Further, even if the fuel particles 10a fall on the inner bottom portion of the combustion section 4 as the powder biomass fuel 10 is used in the burner 5, it can be burned in the combustion section 4 by the combustion means 8. Therefore, it is possible to prevent the deposit of the fuel particles 10a from being generated at the inner bottom portion of the combustion unit 4.

  Therefore, the boiler 1 according to the present embodiment has a problem that when the burner 5 is shut down, the combustion portion 4 generates a deposit and smoke or odor is generated. It is possible to prevent problems such as abnormal combustion and abnormal combustion accompanied by incomplete combustion.

  In addition, about the powder biomass fuel 10 used with the burner 5, information, such as the woody biomass used as the manufacturing raw material, the grinding means and grinding conditions used for the grinding process, and the particle size distribution of the produced powder biomass fuel 10, On the basis, the amount of fuel particles 10a that may be discharged from the burner 5 to the combustion unit 4 can be assumed in advance. Therefore, the supply amount of the combustion air 11 supplied from the blower 15 to the air supply pipe 12b is determined according to the amount of the fuel particles 10a assumed to be discharged from the burner 5 to the combustion unit 4 as described above. do it.

  Although the burner 5 has been described as using the powder biomass fuel 10 having an average particle size of about 100 μm, the boiler 1 of the present embodiment has a powder biomass having a larger particle size, for example, a particle size up to about 1500 μm. Fuel 10 can also be used. Moreover, the boiler 1 of this embodiment can also use the pulverized biomass fuel 10 that contains a relatively large amount of moisture of about 30% regardless of the particle size.

  The amount of fuel particles 10a discharged from the burner 5 and falling to the inner bottom portion of the combustion unit 4 increases as the average particle size of the powdered biomass fuel 10 increases and the water content increases. In this case as well, the amount of fuel particles 10a that may be discharged from the burner 5 to the combustion unit 4 is preliminarily estimated based on the particle size distribution of the powder biomass fuel 10 and information on the moisture of the powder biomass fuel 10. can do. Therefore, if the supply amount of the combustion air 11 to be supplied from the blower 15 to the air supply pipe 12b is determined according to the assumed amount of the fuel particles 10a, the fuel particles 10a dropped on the inner bottom portion of the combustion unit 4 Can be burned in the combustion section 4.

  Therefore, the boiler 1 of the present embodiment has an advantage that the powder biomass fuel 10 having various particle sizes and moisture can be used as the fuel for the burner 5 and stable operation can be continued even in that case.

  Furthermore, since the boiler 1 of this embodiment can burn the fuel particles 10a discharged from the burner 5 to the combustion unit 4 in the combustion unit 4, the heat generated by the combustion of the fuel particles 10a is also generated by the combustion unit 4 Can be used to heat the combustion gas 14 that flows into each smoke pipe 6 and is used for heat exchange with the water 3. Further, in the combustion unit 4, combustion can be promoted even for the combustible matter adhering in an unburned state to the soot dust 21 generated by the combustion of the powdered biomass fuel 10 in the burner 5. The accompanying unburned matter can be reduced. Therefore, the boiler 1 of this embodiment also has the advantage that the loss of an unburned part can be reduced.

[Second Embodiment]
FIG. 2 shows a boiler 1a of the second embodiment. 2 that are the same as those shown in FIG. 1 are marked with the same symbols and descriptions of them will be omitted.

  In the boiler 1a of the second embodiment, in the same configuration as that of the first embodiment, the combustion means 8 is replaced with a configuration in which the combustion section 4 is provided with the air supply pipe 12b, and the combustion means 8 is replaced with a burner in the combustion section 4. 5 is provided with a function of introducing a flame from the flame outlet 5c obliquely downward toward the inner bottom of the combustion section 4.

  As shown in FIG. 2, the combustion means 8 in the present embodiment is formed by bending the flame outlet 5 c of the burner 5 so as to be obliquely downward, and this burner 5 is formed in the combustion section 4 using a cylindrical member 9. It has an installed configuration. Thereby, the burner 5 can inject the flame which arises by combustion of the pulverized biomass fuel 10 from the flame outlet 5c diagonally downward to the inner side of the combustion part 4, that is, toward the inner bottom part of the combustion part 4. .

  Furthermore, it is preferable that the air supply pipe 12c is installed obliquely downward on the peripheral wall of the flame outlet 5c in the burner 5. According to this configuration, the combustion air 11 can be supplied obliquely downward into the combustion unit 4 from the air supply pipe 12c.

  The boiler 1a of this embodiment having such a configuration can heat the water 3 by operating in the same manner as the boiler 1 of the first embodiment, and can supply hot water and steam to the outside.

  The burner 5 can eject a flame generated by the combustion of the pulverized biomass fuel 10 obliquely downward toward the inner bottom portion of the combustion portion 4 along the flame outlet 5c. Further, along with the flame, the combustion gas 14 can also be sent so as to spread toward the inner bottom of the combustion section 4.

  Further, the combustion air 11 can be supplied from the air supply pipe 12 c toward the inner bottom of the combustion unit 4.

  As a result, the fuel particles 10a discharged from the burner 5 and falling to the inner bottom portion of the combustion section 4 are ignited and burned because heat and oxygen necessary for ignition and combustion are supplied. Moreover, since the flame ejected from the burner 5 and the flame due to the combustion of the fuel particles 10a are continuously generated inside the combustion section 4, the combustion of the fuel particles 10a can be stabilized. For this reason, the fuel particles 10a falling on the inner bottom portion of the combustion portion 4 are burned out sequentially.

  Therefore, the effect similar to the boiler 1 of 1st Embodiment can be acquired also by the boiler 1a of this embodiment.

[Third Embodiment]
FIG. 3 shows a boiler 1b according to the third embodiment.

  In FIG. 3, only the combustion part 4 and the burner 5 arranged at the lower part of the can body 2 are shown, and the illustration of the smoke pipe 6, the combustion gas collecting part 7 and the like is omitted. 3, the same components as those shown in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted.

  In the boiler 1b of the present embodiment, in the same configuration as that of the first embodiment, the combustion means 8 is replaced with a configuration in which the combustion unit 4 includes the air supply pipe 12b, and the combustion means 8 is the same as that of the second embodiment. In addition, the combustion part 4 is provided with a function of introducing a flame from the flame outlet 5 c of the burner 5 obliquely downward toward the inner bottom part of the combustion part 4.

  As shown in FIG. 3, the combustion means 8 in the present embodiment has a configuration in which the entire burner 5 is obliquely installed so that the flame outlets 5 c of the burner 5 are arranged obliquely downward.

  As a specific configuration in this case, for example, the cylindrical member 9 is disposed between the combustion member 4 side and the can body 2 side between the circumferential portion of the side wall portion 4c of the combustion portion 4 and the side wall of the can body 2. It may be provided in a slanting posture so as to be lower, and the flame outlet 5 c of the burner 5 may be inserted and attached to the cylindrical member 9 from the outside of the can body 2. Of course, as long as the entire burner 5 can be installed obliquely, the burner 5 may be mounted on the combustion unit 4 in any configuration other than that illustrated.

  Further, similarly to the second embodiment, it is preferable that the air supply pipe 12 c is installed obliquely downward on the peripheral wall of the flame outlet 5 c in the burner 5.

  The boiler 1b of this embodiment having such a configuration can heat the water 3 by operating in the same manner as the boiler 1 of the first embodiment, and can supply hot water and steam to the outside.

  Since the burner 5 is arranged in such a posture that the flame outlet 5c is obliquely downward, the flame generated by the combustion of the powdered biomass fuel 10 is transferred to the flame outlet 5c in the same manner as the burner 5 in the second embodiment. It can be ejected obliquely downward toward the inner bottom portion of the along combustion portion 4. Further, along with the flame, the combustion gas 14 can also be sent so as to spread toward the inner bottom of the combustion section 4.

  Further, the combustion air 11 can be supplied from the air supply pipe 12 c toward the inner bottom of the combustion unit 4.

  As a result, the fuel particles 10a having the unburned portion discharged from the burner 5 and falling to the inner bottom portion of the combustion unit 4 are supplied with heat and oxygen necessary for ignition and combustion, as in the second embodiment. Therefore, it ignites and burns. Moreover, since the flame ejected from the burner 5 and the flame due to the combustion of the fuel particles 10a are continuously generated inside the combustion section 4, the combustion of the fuel particles 10a can be stabilized. For this reason, the fuel particles 10a falling on the inner bottom portion of the combustion portion 4 are burned out sequentially.

  Therefore, the effect similar to the boiler 1 of 1st Embodiment can be acquired also by the boiler 1b of this embodiment.

  In the boiler 1a of the second embodiment and the boiler 1b of the third embodiment, the combustion air 11 is positively supplied from the air supply pipe 12c toward the fuel particles 10a falling on the inner bottom portion of the combustion unit 4. Although the structure to show is shown, you may make it supply the combustion air 11 of the quantity equivalent to the supply quantity from this air supply pipe | tube 12c to the combustion chamber 5a of the burner 5 as surplus air.

  In this case, since surplus air is supplied to the combustion chamber 5a of the burner 5, the combustion of the pulverized biomass fuel 10 in the combustion chamber 5a of the burner 5 may be somewhat unstable. The combustion gas 14 including the combustion air 11 corresponding to the excess air can be sent together with the flame toward the inner bottom of the flame.

  Therefore, even with this configuration, the fuel particles 10a falling on the inner bottom portion of the combustion unit 4 can be ignited and burned. In the case of this configuration, the installation of the air supply pipe 12c can be omitted.

  In addition, this invention is not limited to the thing of each above-mentioned embodiment, For example, the burner 5 is not limited only to the shape of illustration, Combusting the powder biomass fuel 10 to be used Any shape can be used as long as it can be performed.

  As the powdery biomass fuel 10, those derived from woody biomass have been exemplified. However, as long as the fuel is derived from biomass and pulverized to a predetermined particle size, it is derived from plants other than wood and from microorganisms. The powder biomass fuel 10 may be used.

  The size of each component device such as the can body 2, the combustion unit 4, the combustion gas collecting unit 7, the smoke tube 6, the burner 5, the dimensional ratio thereof, and the number of the smoke tubes 6 are for convenience of illustration. It does not reflect the actual device configuration.

  The can 2, the combustion part 4, and the combustion gas collecting part 7 are preferably cylindrical in order to have a pressure-resistant structure, but may have any shape other than the cylindrical shape.

  The arrangement of the combustion part 4, the combustion gas collecting part 7, and the smoke pipe 6 in the can 2 may be other than that shown in the figure.

  Of course, various modifications can be made without departing from the scope of the present invention.

DESCRIPTION OF SYMBOLS 1,1a, 1b Boiler 2 Can body 3 Water 4 Combustion part 5 Burner 5c Flame outlet 6 Smoke pipe 8 Combustion means 10 Powdered biomass fuel 10a Fuel particle 12a Air supply pipe 12b Air supply pipe 12c Air supply pipe 13 Powder fuel supply tube

Claims (5)

A can body in which water is stored;
A combustion section disposed at a lower portion in the can body;
A plurality of smoke pipes arranged extending in the vertical direction in the can and connected to the combustion section;
In a boiler comprising a burner attached to the combustion part,
The burner includes a combustion chamber that generates a flame by combustion of powdered biomass fuel inside, and a powder fuel supply pipe that supplies the powdered biomass fuel to one end side in the axial direction of the combustion chamber is connected, The other end side in the axial direction of the combustion chamber is a flame outlet that blows the flame and combustion gas into the combustion section ,
The combustion portion includes a combustion means for fuel particles that are accompanied by a flame ejected from the flame ejection port of the burner and discharged from the flame ejection port and dropped to the inner bottom portion of the combustion portion,
Each of the smoke pipes collects the combustion gas blown into the combustion section at an upper portion in the can body that communicates with the outside of the can body.
A boiler characterized by that. The combustion section includes an air supply pipe that blows combustion air obliquely downward toward the inner bottom of the combustion section,
The vertical arrangement position of the air supply pipe in the combustion section is above the vertical arrangement position of the flame outlet in the combustion section,
The boiler according to claim 1, wherein the combustion means is constituted by the air supply pipe. The combustion means has a function of introducing a flame from a flame outlet of the burner into the combustion part obliquely downward toward an inner bottom part of the combustion part ,
Vertical position of the boiler according to claim 1, wherein the upper der Rukoto than the vertical arrangement positions of the flame vent in the combustion portion of the combustion means in said combustion unit. The burner comprises a configuration in which the flame outlet is bent obliquely downward,
The boiler according to claim 3, wherein the combustion means is provided with a burner having the above configuration in the combustion section. The burner has a posture inclined obliquely so that the flame outlet is obliquely downward,
The boiler according to claim 3, wherein the combustion means is provided with a burner in the posture.

Images