JP2019108994A - Circulation fluidized bed combustion furnace plant - Google Patents

Abstract

To provide a circulation fluidized bed combustion furnace plant capable of reducing an installation space.SOLUTION: A circulation fluidized bed combustion furnace plant 1 includes: a fuel tank 2 in which a fuel is accumulated; a fluidized bed furnace 3 for fluidizing fluid sand by air and for combusting the fuel; a cyclone 4 provided on an outlet side of the fluidized bed furnace 3 and for separating a combustion gas and the fluid sand; an outside heat exchanger 7 in which at least part of the fluid sand separated in the cyclone 4 is supplied and which circulates the heat-exchanged fluid sand in the fluidized bed furnace 3; a first fuel supply passage 8 for supplying the fuel with respect to the fluidized bed furnace 3 from the fuel tank 2; and a second fuel supply passage 9 for supplying the fuel with respect to the outside heat exchanger 7 from the fuel tank 2.SELECTED DRAWING: Figure 1

Description

  The present disclosure relates to a circulating fluidized bed combustion furnace plant.

  A circulating fluidized bed (CFB: Circulating) improves combustion efficiency by flowing fuel and fluidized sand (for example, particles mainly composed of SiO 2 such as borax) in a furnace by air supplied from a furnace bottom to form a fluidized bed. Fluidized Bed) combustion furnace plants are known.

  The circulating fluidized bed combustion furnace plant can burn a wide range of fuels (eg, bituminous coal, lignite, petroleum coke, woody biomass, paper sludge, RDF, waste tires, etc.) and has high combustion efficiency.

  In a circulating fluidized bed combustion furnace plant, there is a thing of composition which has an external heat exchanger which uses heat which fluid sand has in order to improve thermal efficiency further (for example, patent documents 1).

Patent No. 3686227

  However, when installing an external heat exchanger in the circulating fluidized bed combustion furnace plant, the installation space has been increased. That is, the external heat exchanger also affects the installation space of the entire circulating fluidized bed combustion furnace plant because the apparatus becomes large in order to secure the necessary heat transfer area.

  The circulating fluidized bed combustion furnace plant according to the present disclosure is made in view of such circumstances, and aims to reduce the installation space.

  According to some embodiments of the present disclosure, a fuel tank in which fuel is accumulated, a fluidized bed furnace for flowing fluidized sand with air to burn the fuel, and an outlet side of the fluidized bed furnace, which are provided with combustion gases And a cyclone for separating the fluid sand, and an external heat exchanger which supplies at least a part of the fluid sand separated by the cyclone and exchanges the heat-exchanged fluid sand to the fluidized bed furnace. A first fuel supply passage for supplying the fuel from the fuel tank to the fluidized bed furnace, and a second fuel supply passage for supplying the fuel to the external heat exchanger from the fuel tank; It is a circulating fluidized bed combustion furnace plant equipped with

  According to the above configuration, since the fuel is also supplied from the fuel tank to the external heat exchanger via the first fuel supply passage, the temperature inside the external heat exchanger can be further raised. It is possible. Specifically, in the external heat exchanger, since the fuel supplied from the fuel tank is burned by the heat of the fluidized sand supplied from the cyclone to the external heat exchanger, compared with the case where the fuel is not supplied from the fuel tank. Thus, the temperature in the external heat exchanger can be raised.

  In addition, since the temperature inside the external heat exchanger can be made higher, it is possible to reduce the heat transfer area in the external heat exchanger. As a result, the overall size of the external heat exchanger can be made compact, and further, the restriction of the installation space can be expected to be alleviated.

  In the circulating fluidized bed combustion furnace plant, the external heat exchanger includes an evaporator to which boiler feed water is supplied, and a superheater to which steam generated using the combustion gas is supplied, each of which is a partition wall It may be separated.

  According to the configuration as described above, the external heat exchanger is composed of an evaporator and a superheater, each separated by a partition wall. For this reason, when heat exchange is performed with the fluidized sand in each of the evaporator and the superheater, interference with the other device can be prevented. Specifically, when the external heat exchanger is composed of an evaporator and a superheater, the temperature of the fluidized sand falls more rapidly in the evaporator where heat exchange is performed between the boiler feed water and the fluidized sand Do. However, since the evaporator and the superheater are separated by the partition wall, even if the temperature of the fluidized sand in the evaporator falls rapidly, it does not affect the fluidized sand in the superheater. That is, by providing the partition wall, even if heat exchange is performed in the evaporator, it is possible to prevent the reduction in the heat exchange performance in the superheater.

  In the circulating fluidized bed combustion plant, the external heat exchanger includes an evaporator to which boiler feed water is supplied, a superheater to which steam generated using the combustion gas is supplied, and steam discharged from a high pressure turbine May be supplied by regenerators, each of which is separated by a partition.

  According to the configuration as described above, the external heat exchanger is composed of an evaporator, a superheater, and a reheater, each separated by a partition wall. Therefore, in each device (evaporator, superheater, and reheater), interference with other devices can be prevented when heat exchange is performed with the fluidized sand. Specifically, since the temperature of the fluid sand and the temperature at which heat exchange is performed is different in each device, the temperature drop characteristics of the fluid sand in each device are different. However, by being separated by the partition walls, the temperature lowering characteristics of the flowing sand in one device do not interfere with the temperature lowering characteristics of the flowing sand in the other device. In addition, since the reheater can reheat the steam discharged from the high pressure turbine, cycle efficiency can be enhanced.

  In the circulating fluidized bed combustion furnace plant, the second fuel supply passage may have a control valve that adjusts the supply amount of the fuel.

  According to the configuration as described above, the internal temperature of the external heat exchanger can be controlled by controlling the amount of fuel supplied to the external heat exchanger using the control valve. For example, the internal temperature of the external heat exchanger and the internal temperature of the fluidized bed furnace may be approximately equal. That is, since the fluidized sand supplied (circulated) from the external heat exchanger to the fluidized bed furnace can be made substantially equal to the internal temperature of the fluidized bed furnace, the deterioration of the furnace desulfurization can be suppressed, and Dissolution of fluidized sand can be prevented.

  In the circulating fluidized bed combustion furnace plant, the second fuel supply passage is a fuel supply passage for an evaporator for supplying the fuel to the evaporator in the external heat exchanger, and the superheater in the external heat exchanger. And the fuel supply path for the superheater for supplying the fuel, and at least one of the fuel supply path for the evaporator and the fuel supply path for the superheater has a control valve for adjusting the supply amount of the fuel. You may do it.

  According to the above configuration, when the external heat exchanger is composed of an evaporator and a superheater, it is possible to adjust the amount of fuel supplied to each of the evaporator and the superheater. Specifically, when controlling the adjustment valve in the fuel supply path for the evaporator to control the amount of fuel supplied to the evaporator, it is possible to control the temperature rise of the boiler feed water supplied to the evaporator. Further, in the case of controlling the amount of fuel supplied to the superheater by controlling the regulating valve in the superheater fuel supply passage, it is possible to control the temperature rise of the steam supplied to the superheater. In particular, by controlling the adjusting valve in the fuel supply passage for the superheater, for example, when the overheat reducer is used in the circulating fluidized bed combustion furnace, the frequency of use of the overheat reducer can be reduced, thereby reducing the overheat reduction. Can save water used in

  In the circulating fluidized bed combustion furnace plant, the second fuel supply passage is a fuel supply passage for an evaporator for supplying the fuel to the evaporator in the external heat exchanger, and the superheater in the external heat exchanger. A superheater fuel supply passage for supplying the fuel to the heat exchanger, and a reheater fuel supply passage for supplying the fuel to the reheater in the external heat exchanger; At least one of the superheater fuel supply passage and the reheater fuel supply passage may have a control valve for adjusting the fuel supply amount.

  According to the above configuration, when the external heat exchanger is composed of the evaporator, the superheater and the reheater, the amount of fuel supplied to each of the evaporator, the superheater and the reheater is It can be adjusted. Specifically, when controlling the adjustment valve in the fuel supply path for the evaporator to control the amount of fuel supplied to the evaporator, it is possible to control the temperature rise of the boiler feed water supplied to the evaporator. Further, in the case of controlling the amount of fuel supplied to the superheater by controlling the regulating valve in the superheater fuel supply passage, it is possible to control the temperature rise of the steam supplied to the superheater. In particular, by controlling the adjusting valve in the fuel supply passage for the superheater, for example, when the overheat reducer is used in the circulating fluidized bed combustion furnace, the frequency of use of the overheat reducer can be reduced, thereby reducing the overheat reduction. Can save water used in Also, when controlling the adjustment valve in the reheater fuel supply path to control the amount of fuel supplied to the reheater, the temperature rise of the steam discharged from the high pressure turbine supplied to the reheater is controlled. be able to.

  According to the circulating fluidized bed combustion furnace plant according to the present disclosure, it is possible to reduce the installation space in the circulating fluidized bed combustion furnace plant.

It is a figure showing a schematic structure of a circulating fluidized bed combustion furnace plant concerning a 1st embodiment of this indication. It is a figure showing a schematic structure of an external heat exchanger in a circulating fluidized bed combustion furnace plant concerning a 2nd embodiment of this indication. It is a figure showing a schematic structure of a circulating fluidized bed combustion furnace plant concerning a 2nd embodiment of this indication. It is a figure showing a schematic structure of an external heat exchanger in a circulating fluidized bed combustion furnace plant concerning a 3rd embodiment of this indication. It is a figure showing a schematic structure of a circulating fluidized bed combustion furnace plant concerning a 3rd embodiment of this indication.

First Embodiment
Hereinafter, a first embodiment of a circulating fluidized bed combustion furnace plant 1 according to the present disclosure will be described with reference to the drawings.
FIG. 1 is a view showing a schematic configuration of a circulating fluidized bed combustion furnace plant 1 according to a first embodiment of the present disclosure. As shown in FIG. 1, the circulating fluidized bed combustion furnace plant 1 according to the present embodiment includes a fuel tank 2, a fluidized bed furnace 3, a cyclone 4, a convection heat transfer unit 5, a seal pot 6, and external heat. The exchanger 7, the first fuel supply passage 8 and the second fuel supply passage 9 are provided as main components.

  In the fuel tank 2, fuel used in the fluidized bed furnace 3 and the external heat exchanger 7 is accumulated. The circulating fluidized bed combustion furnace plant 1 can burn a wide range of fuels. The fuel is, for example, coal (bituminous coal, bituminous coal, lignite, anthracite etc.), petroleum coke, woody biomass, paper sludge, RPF (Refuse Paper & Plastic Fuel), waste tires, dehydrated sludge, municipal waste and the like. In the circulating fluidized bed combustion furnace plant 1, the fuel is accumulated in a pulverized state in the fuel tank 2 in order to make it possible to burn the fuel. The fuel tank 2 is connected to the fluidized bed furnace 3 via the first fuel supply passage 8, and can supply the fuel via the first fuel supply passage 8. Further, the fuel tank 2 is connected to the external heat exchanger 7 via the second fuel supply passage 9, and can supply the fuel via the second fuel supply passage 9.

In the fluidized bed furnace 3 (combustor), air flows fluidized sand and burns the fuel supplied from the first fuel supply passage 8 to generate high temperature gas (combustion gas). Specifically, in the fluidized bed furnace 3, the fluidized sand in the fluidized bed furnace 3 is made to flow by high pressure air (gas) supplied from the air nozzle 10 provided at the furnace bottom to form a fluidized bed. . By forming the fluidized bed, fuel, fluidized sand and air are mixed in the furnace to improve the combustion efficiency. During normal operation of the fluidized bed furnace 3, air (oxygen) is supplied as a gas from the air nozzle 10, but when stopped, an inert gas (nitrogen gas or the like) may be introduced. The fluidized sand is, for example, particles mainly composed of SiO ₂ such as borax. While the temperature in the furnace in a general boiler is 1400 ° C. to 1500 ° C., the temperature in the fluidized bed furnace 3 is as low as 800 ° C. to 900 ° C. It can be suppressed. In addition, it is possible to carry out in-furnace desulfurization by supplying limestone into the fluidized bed furnace 3. The air supplied to the fluidized bed furnace 3 is supplied through the air nozzle 10 after the air taken in by the push-in ventilator 16 is preheated in the air preheater 17 using the combustion gas.

  The cyclone 4 is provided on the outlet side of the fluidized bed furnace 3 and separates the combustion gas and the fluidized sand. Fluidized sand is also discharged from the fluidized bed furnace 3 together with the combustion gas, but since the combustion gas and the fluidized sand are in a mixed state, the cyclone 4 separates the combustion gas and the fluidized sand. Then, the combustion gas separated by the cyclone 4 is supplied to the convection heat transfer unit 5 and the fluidized sand is supplied to the seal pot 6.

  In the convective heat transfer unit 5, the combustion gas separated by the cyclone 4 is supplied, and heat exchange is performed between the combustion gas and the boiler feed water to generate superheated steam. Therefore, the convective heat transfer unit 5 includes the economizer 11, the evaporation tube 12, and the superheater 13. The convection heat transfer unit 5 may be configured of the evaporation tube 12 and the superheater 13. The economizer 11 preheats the boiler feed water using relatively low temperature combustion gas (for example, combustion gas after heat exchange has been performed by the superheater 13 etc.) in the convection heat transfer section 5. By preheating the boiler feed water by the economizer 11, the combustion gas loss can be reduced, and the thermal stress of the structure (e.g., heat transfer pipe) of the evaporation pipe 12 and the superheater 13 can be alleviated. The boiler feed water preheated by the economizer 11 is supplied to the evaporation pipe 12 and is heat-exchanged with the high temperature combustion gas to become high pressure steam. Then, the superheater 13 generates the superheated steam from the high pressure steam using the heat of the combustion gas. The generated superheated steam is supplied to a turbine (not shown) through the external heat exchanger 7 and used for power generation and the like. In addition, about the circulation of the boiler feed water supplied to the convection heat-transfer part 5, a natural circulation system, a forced circulation system, a through-flow system etc. are employable suitably. In addition, the combustion gas which finished heat exchange in the convection heat-transfer part 5 is discharge | released to air | atmosphere from a chimney, after passing through the air preheater 17 and the bag filter 18. As shown in FIG.

  The seal pot 6 separately supplies the fluidized sand separated by the cyclone 4 to the external heat exchanger 7 and the fluidized bed furnace 3. Specifically, a line 25 for supplying fluid sand directly from the seal pot 6 to the fluidized bed furnace 3 and a line for delivering fluid sand from the seal pot 6 to the external heat exchanger 7 to the seal pot 6 23 are connected.

  In addition, the ash removal valve 15 is provided in the line 23, and by adjusting the ash removal valve 15, the amount of flowing sand supplied from the seal pot 6 to the external heat exchanger 7 can be adjusted. . Fluidized sand not supplied from the seal pot 6 to the external heat exchanger 7 is supplied (circulated) to the fluidized bed furnace 3 via the line 25. That is, by adjusting the amount of fluidized sand supplied from the seal pot 6 to the external heat exchanger 7 by the ash takeout valve 15, the amount of fluidized sand supplied directly from the seal pot 6 to the fluidized bed furnace 3 is adjusted It is possible to adjust the temperature of the fluidized bed furnace 3. For this reason, even when partial load or when the calorific value of the fuel changes, the in-furnace temperature of the fluidized bed furnace 3 can be optimized for combustibility and in-furnace desulfurization.

  The external heat exchanger 7 is a fluidized bed type external heat exchange (FBHE: Fluidized Bed Heat Exchanger), and at least a part of the fluidized sand separated by the cyclone 4 is supplied, and the fluidized sand which has been heat exchanged is made to flow The layer furnace 3 is circulated. Specifically, the external heat exchanger 7 is supplied with fluidized sand adjusted by the ash takeout valve 15 from the cyclone 4 through the seal pot 6. In the external heat exchanger 7, fluid sand flows by the high pressure air supplied from the blower 14, and the fuel supplied via the second fuel supply passage 9 is dispersed to the fluid sand which has flowed. The dispersed fuel generates combustion gas by burning with the heat of fluidized sand in a high temperature state, and raises the temperature inside the external heat exchanger 7 (the temperature of the fluidized sand or the like). And in the external heat exchanger 7, heat exchange is performed in the evaporator 30 grade | etc., Comprised. Even if fuel is not sprayed, the temperature inside the external heat exchanger 7 (especially the temperature of the fluidized sand) is about 550 ° C to 700 ° C, but it is possible to spray the fuel against the fluidized sand and burn it. The temperature inside the external heat exchanger 7 can be raised to about 850.degree. The fluidized sand and the combustion gas in the external heat exchanger 7 are returned to the fluidized bed furnace 3 through the line 24 by the high pressure air supplied from the blower 14. It is also possible to adjust the amount of high pressure air by controlling the blower 14 and to adjust the amount of fluidized sand supplied from the external heat exchanger 7 to the fluidized bed furnace 3. The temperature inside the external heat exchanger 7 is not limited to 850 ° C., and can be appropriately designed according to the specifications of the fluidized bed furnace 3 and the like.

  The external heat exchanger 7 comprises an evaporator 30 and a superheater 31. For this reason, the heat transfer pipe of the evaporator 30 and the heat transfer pipe of the superheater 31 are disposed inside the external heat exchanger 7. The boiler feed water is supplied to the evaporator 30, and the boiler feed water is heated by exchanging heat with the fluid sand supplied to the external heat exchanger 7 while flowing inside the heat transfer pipe. The boiler feed water heated in the evaporator 30 is supplied to the economizer 11 in the convection heat transfer unit 5 and further heated. Superheated steam generated by using the combustion gas in the superheater 31 in the convection heat transfer unit 5 is supplied to the superheater 31, and the superheated steam is supplied to the external heat exchanger 7 while flowing inside the heat transfer pipe. Heat exchange with the flowing sand is carried out to further overheat. The superheated steam superheated in the superheater 31 is supplied to a turbine and used for power generation and the like.

  That is, in the present embodiment, the boiler feed water supplied from the condensate system or the like is the evaporator 30 in the external heat exchanger 7, the economizer 11 in the convection heat transfer unit 5, the evaporation tube 12 in the convection heat transfer unit 5, The superheater 13 in the heat transfer section 5 and the superheater 31 in the external heat exchanger 7 are sequentially heated and heated to become superheated steam, which is supplied to the turbine.

  In the present embodiment, although the external heat exchanger 7 has been described as being configured of the evaporator 30 and the superheater 31, the external heat exchanger 7 includes the evaporator 30, the superheater 31, and the reheater. It may be composed of 32. When the external heat exchanger 7 is composed of the evaporator 30, the superheater 31 and the reheater 32, the heat transfer tubes of the evaporator 30 and the heat transfer tubes of the superheater 31 are provided inside the external heat exchanger 7. The heat pipe and the heat transfer pipe of the reheater 32 are disposed, and heat exchange is performed with the flowing sand (and the combustion gas).

  In the reheater 32, the steam discharged from the high pressure turbine is supplied, the supplied steam is reheated, and the reheated steam is supplied to the low pressure turbine. Specifically, the circulating fluidized bed combustion furnace plant 1 includes a steam turbine (not shown), and the steam turbine is configured by combining a high pressure turbine and a low pressure turbine, for example. The superheated steam generated by the convection heat transfer unit 5 and the external heat exchanger 7 is first supplied to a high pressure turbine to drive the turbine. The steam finished work in the high pressure turbine is in a state close to wet steam and the temperature has dropped, so it is reheated by the reheater 32 in the external heat exchanger 7 and supplied again to the low pressure turbine as superheated steam. By using the reheater 32, cycle efficiency can be improved. If the steam turbine is composed of a high pressure turbine, an intermediate pressure turbine, and a low pressure turbine, the reheater 32 may reheat the steam discharged from the high pressure turbine and supply it to the intermediate pressure turbine The steam discharged from the intermediate pressure turbine may be reheated and supplied to the low pressure turbine.

  The first fuel supply passage 8 is a pipe for supplying fuel from the fuel tank 2 to the fluidized bed furnace 3. Specifically, as shown in FIG. 1, one end of the first fuel supply passage 8 is connected to the fuel tank 2, and the other end is connected to the fluidized bed furnace 3. Further, the first fuel supply passage 8 has a feeder 19 for equalizing the amount of fuel passing through the inside of the first fuel supply passage 8 and a control valve 20 for adjusting the amount of supplied fuel. The fuel whose supply amount has been adjusted by the adjustment valve 20 is supplied to the fluidized bed furnace 3.

  The second fuel supply passage 9 is a pipe for supplying fuel from the fuel tank 2 to the external heat exchanger 7. Specifically, as shown in FIG. 1, the second fuel supply passage 9 has one end connected to the fuel tank 2 and the other end connected to the external heat exchanger 7. Further, the second fuel supply passage 9 has a feeder 22 for equalizing the amount of fuel passing inside the first fuel supply passage 8 and a control valve 21 for adjusting the supply amount of fuel. The fuel whose supply amount has been adjusted by the adjustment valve 21 is supplied to the external heat exchanger 7. The amount of fuel supplied to the external heat exchanger 7 via the second fuel supply passage 9 is within 20% of the amount of fuel supplied to the fluidized bed furnace 3 via the first fuel supply passage 8. It is preferable to be adjusted. The fuel supply ratio to the external heat exchanger 7 is determined from the amount of air supplied to the external heat exchanger 7, and is determined so as not to cause oxygen shortage in the external heat exchanger 7.

  Note that the amount of fuel supplied is adjusted by controlling the adjustment valve 21 provided in the second fuel supply passage 9 to make the temperature inside the external heat exchanger 7 equal to the temperature inside the fluidized bed furnace 3 Is preferred. Therefore, control of the adjustment valve 21 provided in the second fuel supply passage 9 may be automatically controlled. In this case, a measuring device for measuring the temperature inside the fluidized bed furnace 3 and the external heat exchanger 7 and a control device for controlling the adjusting valve 21 based on the measurement result by the measuring device are further provided. Good. That is, when the temperature inside the external heat exchanger 7 is lower than the temperature inside the fluidized bed furnace 3 obtained from the measuring device, the control device opens the opening degree of the adjustment valve 21 by a predetermined amount, The supply amount is increased to raise the temperature inside the external heat exchanger 7. When the temperature inside the external heat exchanger 7 is higher than the temperature inside the fluidized bed furnace 3 obtained from the measuring device, the control device closes the opening degree of the adjustment valve 21 by a predetermined amount, The supply amount is reduced and the temperature inside the external heat exchanger 7 is reduced. The control of the opening degree of the adjustment valve 21 may be determined in advance, or based on the difference between the temperature inside the fluidized bed furnace 3 and the temperature inside the external heat exchanger 7. It may be determined.

  Thus, the amount of fuel supplied is adjusted by controlling the adjustment valve 21 provided in the second fuel supply passage 9, and the temperature inside the external heat exchanger 7 is made equal to the temperature inside the fluidized bed furnace 3. can do. That is, since the temperature of the fluidized sand supplied (circulated) from the external heat exchanger 7 to the fluidized bed furnace 3 can be made substantially equal to the internal temperature of the fluidized bed furnace 3, the deterioration of the furnace desulfurization is suppressed It is possible to prevent the dissolution of fluidized sand and the like.

  In the present embodiment, as shown in FIG. 1, the case where the first fuel supply passage 8 and the second fuel supply passage 9 are directly connected to the fuel tank 2 is described, but the first fuel supply is described. The configurations of the passage 8 and the second fuel supply passage 9 are not limited to those shown in FIG. 1 as long as fuel is supplied from the fuel tank 2 to the fluidized bed furnace 3 and the external heat exchanger 7, respectively. That is, one end side of the common supply path in which the first fuel supply path 8 and the second fuel supply path 9 are shared is connected to the fuel tank 2 and the other end is the first fuel supply path 8 and the second fuel supply path 9 may be branched.

  Next, circulation of fluidized sand in the above-described circulating fluidized bed combustion furnace plant 1 will be described with reference to FIG.

  First, the fluidized sand flows in the fluidized bed furnace 3 by high pressure air supplied from the bottom of the furnace to form a fluidized bed. The fluidized bed is heated below the ignition point of carbon and gas. The fluidized sand agitates the fuel supplied through the first fuel supply passage 8 substantially equally to the left, right, up and down, and burns the fuel by the heat of the fluidized sand which is in a high temperature state, thereby generating a high temperature gas (combustion gas) generate. The temperature inside the fluidized bed furnace 3 (in particular, the temperature of the fluidized sand) reaches about 850 ° C.

  Fluidized sand and combustion gas are discharged from the upper portion of the fluidized bed furnace 3 in a mixed state and supplied to the cyclone 4. In the cyclone 4, the fluidized sand is centrifuged with respect to the combustion gas, falls by gravity, and is supplied to the seal pot 6 from the lower part of the cyclone 4. The combustion gas is discharged from the upper part of the cyclone 4 and supplied to the convection heat transfer unit 5.

  Fluidized sand supplied to the seal pot 6 is supplied to the external heat exchanger 7 through the ash takeoff valve 15. The fluidized sand other than the fluidized sand supplied to the external heat exchanger 7 is returned to the fluidized bed furnace 3 via the line 25. The fluidized sand supplied to the external heat exchanger 7 is approximately 550 ° C. to 700 ° C. In the external heat exchanger 7, the fluidized sand is fluidized by the high pressure air supplied from the lower part, and the fuel supplied via the second fuel supply passage 9 is dispersed to the fluidized sand. The dispersed fuel is burned by the heat of fluidized sand in a high temperature state to generate a combustion gas and raise the temperature inside the external heat exchanger 7 (the temperature of the fluidized sand or the like). The temperature inside the external heat exchanger 7 (the temperature of the flowing sand or the like) after the combustion of the fuel becomes about 850 ° C. With the inside of the external heat exchanger 7 in a high temperature state, heat exchange is performed in the configured evaporator 30 and superheater 31 in the external heat exchanger 7. The fluidized sand and the combustion gas in the external heat exchanger 7 are returned to the fluidized bed furnace 3 through the line 24 by the high pressure air supplied from the blower 14. By following the flow path as described above, the fluidized sand circulates through the circulating fluidized bed combustion furnace plant 1, that is, the fluidized bed furnace 3, the cyclone 4, the seal pot 6, and the external heat exchanger 7. In the case where the external heat exchanger 7 is not used, the fluidized sand circulates through the fluidized bed furnace 3, the cyclone 4 and the seal pot 6.

  As described above, according to the circulating fluidized bed combustion furnace plant 1 according to the present embodiment, the fuel is also supplied from the fuel tank 2 to the external heat exchanger 7 via the first fuel supply passage 8. Therefore, the temperature inside the external heat exchanger 7 can be raised more. Specifically, since the fuel is burned by the heat of fluidized sand supplied from the cyclone 4 to the external heat exchanger 7, the temperature in the external heat exchanger 7 is compared with the case where the fuel is not supplied from the fuel tank 2. Can be raised.

  Moreover, since the temperature inside the external heat exchanger 7 can be brought to a higher temperature state, it is possible to reduce the heat transfer area in the external heat exchanger 7. Therefore, the overall size of the external heat exchanger 7 can be made compact, and furthermore, the restriction of the installation space can be expected. Specifically, in order to form a fluidized bed using high pressure air in the fluidized bed furnace 3, fluidized sand and fuel gas are discharged from the upper part of the fluidized bed furnace 3 and supplied to the cyclone 4. The fluidized sand separated by the cyclone 4 is supplied to the external heat exchanger 7 based on gravity fall. That is, as shown in FIG. 1, the cyclone 4 is disposed at the upper part of the external heat exchanger 7, and the installation height of the cyclone 4 is the height of the fluidized bed furnace 3 (in particular, the position of the discharge port of fluidized sand and fuel gas) Were constrained. However, by achieving the compactness of the external heat exchanger 7, the installation height of the cyclone 4 can be designed low, and accordingly, the height of the fluidized bed furnace 3 can be designed low as well. It becomes possible. Therefore, the installation space can be reduced as the whole circulating fluidized bed combustion furnace plant 1.

  Further, by controlling the amount of fuel supplied to the external heat exchanger 7 using the control valve 21, the internal temperature of the external heat exchanger 7 can be controlled. For example, the internal temperature of the external heat exchanger 7 and the internal temperature of the fluidized bed furnace 3 can be made substantially equal. That is, since the fluidized sand supplied (circulated) from the external heat exchanger 7 to the fluidized bed furnace 3 can be made substantially equal to the internal temperature of the fluidized bed furnace 3, the deterioration of the furnace desulfurization can be suppressed. Also, the dissolution of fluidized sand can be prevented.

Second Embodiment
Next, a circulating fluidized bed combustion furnace plant 1 according to a second embodiment of the present disclosure will be described.
In the first embodiment described above, the case where the external heat exchanger 7 includes the evaporator 30 and the superheater 31 has been described, but in the present embodiment, the external heat exchanger 7 includes the evaporator 30 and the superheater 31. Further, the evaporator 30 and the superheater 31 are separated by a partition 35. Hereinafter, points of the circulating fluidized bed combustion furnace plant 1 according to the present embodiment which differ from the first embodiment will be mainly described.

  The external heat exchanger 7 in the present embodiment is, as shown in FIG. 2, composed of an evaporator 30 and a superheater 31, which are separated by a partition wall 35. 2 is a schematic view of space division in the external heat exchanger 7, the heat transfer pipes in the evaporator 30 and the superheater 31 are omitted. Further, the shape of the partition wall 35 and the method of dividing the space are not limited to the configuration shown in FIG. 2 and can be appropriately designed.

  Further, as shown in FIG. 3, the second fuel supply passage 9 in the circulating fluidized bed combustion furnace plant 1 according to the present embodiment has an evaporator fuel supply passage 9a and a superheater fuel supply passage 9b. That is, the fuel accumulated in the fuel tank 2 can be supplied to each of the evaporator 30 and the superheater 31 through the evaporator fuel supply passage 9a and the superheater fuel supply passage 9b. In the second fuel supply passage 9 in the present embodiment, as shown in FIG. 3, the second fuel supply passage 9 connected to the fuel tank 2 is connected to the evaporator fuel supply passage 9a and the superheater fuel supply passage 9b. Although the construction is branched, the invention is not limited to this construction. For example, each of the fuel supply path 9a for the evaporator and the fuel supply path 9b for the superheater is connected to the fuel tank 2, and the evaporator 30 and the superheater 31 are It may be configured to be able to be supplied.

  The evaporator fuel supply passage 9 a is a pipe for supplying fuel to the evaporator 30 in the external heat exchanger 7. Specifically, the evaporator fuel supply passage 9a has a feeder 22a for equalizing the amount of fuel passing through the evaporator fuel supply passage 9a and a control valve 21a for adjusting the amount of fuel supply. . The fuel whose supply amount has been adjusted by the adjustment valve 21 a is supplied to the evaporator 30 in the external heat exchanger 7. The fuel is dispersed to the fluidized sand supplied to the evaporator 30 in the external heat exchanger 7 via the evaporator fuel supply passage 9a.

  The superheater fuel supply passage 9 b is a pipe for supplying fuel to the superheater 31 in the external heat exchanger 7. Specifically, the superheater fuel supply passage 9b has a feeder 22b for equalizing the amount of fuel passing through the superheater fuel supply passage 9b and a control valve 21b for adjusting the amount of supplied fuel. . The fuel whose supply amount has been adjusted by the adjustment valve 21 b is supplied to the superheater 31 in the external heat exchanger 7. The fuel is dispersed to the fluidized sand supplied to the superheater 31 in the external heat exchanger 7 via the superheater fuel supply passage 9b.

  In the external heat exchanger 7, the fluidized sand supplied from the cyclone 4 is supplied substantially equally to the evaporator 30 and the superheater 31. Then, in the evaporator 30 and the superheater 31, the fuel whose supply amount is adjusted independently is dispersed through the evaporator fuel supply passage 9a and the superheater fuel supply passage 9b. That is, in the external heat exchanger 7 in the present embodiment, the temperature can be adjusted for each of the evaporator 30 and the superheater 31. Therefore, the heat exchange capacities of the evaporator 30 and the superheater 31 can be controlled independently. In the present embodiment, in the external heat exchanger 7, the fluid sand supplied from the cyclone 4 is substantially equally supplied to the evaporator 30 and the superheater 31, but, for example, the evaporator A large amount of fluidized sand may be supplied to one of the heat exchanger 30 and the superheater 31 that requires a larger amount of heat exchange.

  As described above, according to the circulating fluidized bed combustion furnace plant 1 according to the present embodiment, the external heat exchanger 7 is configured of the evaporator 30 and the superheater 31 and separated by the partition wall 35. For this reason, in each apparatus (the evaporator 30 and the superheater 31), when heat exchange is performed with fluidized sand, interference with another apparatus can be prevented. Specifically, when the external heat exchanger 7 is configured of the evaporator 30 and the superheater 31, the evaporator 30 in which heat exchange is performed between the boiler feed water and the fluidized sand is the temperature of the fluidized sand Decreases rapidly. However, since the evaporator 30 and the superheater 31 are separated by the dividing wall 35, even if the temperature of the fluidized sand in the evaporator 30 is rapidly reduced, the fluidized sand in the superheater 31 is not affected. That is, the heat exchange performance of the superheater 31 can be prevented from being degraded.

  Moreover, when the external heat exchanger 7 is comprised from the evaporator 30 and the superheater 31, the supply amount of the fuel supplied to each of the evaporator 30 and the superheater 31 can be adjusted. Specifically, when controlling the amount of fuel supplied to the evaporator 30 by controlling the adjustment valve 21a in the evaporator fuel supply passage 9a, the temperature rise of the boiler feed water supplied to the evaporator 30 should be controlled. Can. Further, in the case where the control valve 21b in the superheater fuel supply passage 9b is controlled to control the amount of fuel supplied to the superheater 31, the temperature rise of the steam supplied to the superheater 31 can be controlled. In particular, by controlling the adjusting valve 21b in the superheater fuel supply passage 9b, for example, when the overheat reduction device for adjusting (mainly reducing) the temperature of the overheated steam is used in the convection heat transfer unit 5. Can reduce the frequency of use of the overheat reducer, save water used in the overheat reducer, and suppress a decrease in cycle efficiency.

Third Embodiment
Next, a circulating fluidized bed combustion furnace plant 1 according to a third embodiment of the present disclosure will be described.
In the first and second embodiments described above, the external heat exchanger 7 is configured of the evaporator 30 and the superheater 31. However, in the present embodiment, the external heat exchanger 7 is the evaporator 30. , The superheater 31, and the reheater 32, and further, the evaporator 30, the superheater 31, and the reheater 32 are separated by the partition wall 35. Hereinafter, points of the circulating fluidized bed combustion furnace plant 1 according to the present embodiment which are different from the first embodiment and the second embodiment will be mainly described.

  As shown in FIG. 4, the external heat exchanger 7 in the present embodiment is composed of an evaporator 30, a superheater 31 and a reheater 32, which are separated by a partition wall 35. 4 is a schematic view of space division in the external heat exchanger 7, the heat transfer pipes in the evaporator 30, the superheater 31, and the reheater 32 are omitted. Further, the shape of the partition wall 35 and the method of dividing the space are not limited to the configuration shown in FIG. 4 and can be appropriately designed.

  Further, as shown in FIG. 5, the second fuel supply passage 9 in the circulating fluidized bed combustion furnace plant 1 according to the present embodiment is the evaporator fuel supply passage 9a, the superheater fuel supply passage 9b, and the reheater fuel supply passage. And 9c. That is, the fuel accumulated in the fuel tank 2 passes through the evaporator fuel supply passage 9a, the superheater fuel supply passage 9b, and the reheater fuel supply passage 9c to the evaporator 30, the superheater 31, and the reheater. It is made available to each of 32. In the second fuel supply passage 9 in the present embodiment, as shown in FIG. 5, the second fuel supply passage 9 connected to the fuel tank 2 is the evaporator fuel supply passage 9a, the superheater fuel supply passage 9b, and The construction is branched to the reheater fuel supply path 9c. However, the invention is not limited to this configuration. For example, each of the evaporator fuel supply path 9a, the superheater fuel supply path 9b, and the reheater fuel supply path 9c is a fuel tank 2, and may be configured to be able to supply combustion to each of the evaporator 30, the superheater 31, and the reheater 32.

  The reheater fuel supply passage 9 c is a pipe for supplying fuel to the reheater 32 in the external heat exchanger 7. Specifically, the reheater fuel supply passage 9c has a feeder 22c for equalizing the amount of fuel passing through the reheater fuel supply passage 9c, and a control valve 21c for adjusting the amount of supplied fuel. ing. The fuel whose supply amount has been adjusted by the adjustment valve 21 c is supplied to the reheater 32 in the external heat exchanger 7. The fuel is dispersed to the fluidized sand supplied to the space of the reheater 32 in the external heat exchanger 7 through the reheater fuel supply passage 9c.

  In the external heat exchanger 7, the fluidized sand supplied from the cyclone 4 is supplied substantially equally to the evaporator 30, the superheater 31, and the reheater 32. Then, in the evaporator 30, the superheater 31, and the reheater 32, the fuel independently adjusted through the evaporator fuel supply passage 9a, the superheater fuel supply passage 9b, and the reheater fuel supply passage 9c is obtained. It is spread. That is, in the external heat exchanger 7 in the present embodiment, the temperature can be adjusted for each of the evaporator 30, the superheater 31, and the reheater 32. Therefore, the heat exchange capacities of the evaporator 30, the superheater 31, and the reheater 32 can be controlled independently.

  As explained above, according to the circulating fluidized bed combustion furnace plant 1 according to the present embodiment, the external heat exchanger 7 is composed of the evaporator 30, the superheater 31, and the reheater 32, each of which is the partition 35 Separated by For this reason, in each apparatus (the evaporator 30, the superheater 31, and the reheater 32), when heat exchange is performed with fluidized sand, interference with another apparatus can be prevented. Specifically, since the temperature of the fluid sand and the temperature at which heat exchange is performed is different in each device, the temperature drop characteristics of the fluid sand in each device are different. However, separated by the partition walls 35, the temperature lowering characteristics of the flowing sand in one device do not interfere with the temperature lowering characteristics of the flowing sand in the other device. In addition, since the steam discharged from the high pressure turbine can be reheated by the reheater 32, cycle efficiency can be enhanced.

  Also, when the external heat exchanger 7 is configured of the evaporator 30, the superheater 31, and the reheater 32, the amount of fuel supplied to each of the evaporator 30, the superheater 31, and the reheater 32 It can be adjusted. Specifically, when controlling the amount of fuel supplied to the evaporator 30 by controlling the adjustment valve 21a in the evaporator fuel supply passage 9a, the temperature rise of the boiler feed water supplied to the evaporator 30 should be controlled. Can. Further, specifically, when controlling the amount of fuel supplied to the superheater 31 by controlling the adjustment valve 21b in the superheater fuel supply passage 9b, the temperature rise of the steam supplied to the superheater 31 is controlled. be able to. In particular, by controlling the adjusting valve 21b in the superheater fuel supply passage 9b, for example, when the overheat reducer is used in the circulating fluidized bed combustion furnace, the frequency of use of the overheat reducer can be reduced, It is possible to save water used in the overheat reducer. Further, in the case of controlling the amount of fuel supplied to the reheater 32 by controlling the adjustment valve 21c in the reheater fuel supply passage 9c, the temperature of the steam discharged from the high pressure turbine supplied to the reheater 32. You can control the rise.

  The present disclosure is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the invention. In addition, it is also possible to combine each embodiment.

1: circulating fluidized bed combustion furnace plant 2: fuel tank 3: fluidized bed furnace 4: cyclone 5: convection heat transfer part 6: seal pot 7: external heat exchanger 8: first fuel supply passage 9: second fuel supply passage 9a: fuel supply path for evaporator 9b: fuel supply path for superheater 9c: fuel supply path for reheater 10: air nozzle 11: economizer 12: evaporation pipe 13: superheater 14 (in the convection heat transfer section): blower 15 : Ash takeout valve 16: Pushing ventilator 17: Air preheater 18: Bag filter 19: Feeder 20, 21, 21a-21c: Control valve 22, 22a-22c: Feeder 23, 24, 25: Line 30: Evaporator 31 : Superheater 32 (in external heat exchanger) 32: Reheater 35: Bulkhead

Claims (6)

A fuel tank in which fuel is accumulated,
A fluidized bed furnace which causes fluidized sand to flow by air and burns the fuel;
A cyclone provided on the outlet side of the fluidized bed furnace for separating combustion gas and the fluidized sand;
An external heat exchanger which is supplied with at least a part of the fluidized sand separated by the cyclone and which exchanges the heat-exchanged fluidized sand to the fluidized bed furnace;
A first fuel supply passage for supplying the fuel from the fuel tank to the fluidized bed furnace;
A second fuel supply passage for supplying the fuel from the fuel tank to the external heat exchanger;
A circulating fluidized bed combustion furnace plant equipped with   The said external heat exchanger is comprised from the evaporator by which boiler feed water is supplied, and the superheater by which the vapor | steam produced | generated using the said combustion gas is supplied, Each is separated by the partition. Circulating fluidized bed combustion furnace plant.   The external heat exchanger comprises an evaporator to which boiler feed water is supplied, a superheater to which steam generated using the combustion gas is supplied, and a reheater to which steam discharged from a high pressure turbine is supplied. The circulating fluidized bed incinerator plant according to claim 1, wherein each is separated by a dividing wall.   The circulating fluidized bed combustion furnace plant according to any one of claims 1 to 3, wherein the second fuel supply passage has a control valve that adjusts the supply amount of the fuel. The second fuel supply passage is a fuel supply passage for an evaporator that supplies the fuel to the evaporator in the external heat exchanger, and a superheat that supplies the fuel to the superheater in the external heat exchanger. And a fuel supply path for
The circulating fluidized bed combustion furnace plant according to claim 2, wherein at least one of the evaporator fuel supply passage and the superheater fuel supply passage has a control valve for adjusting the supply amount of the fuel. The second fuel supply passage is a fuel supply passage for an evaporator that supplies the fuel to the evaporator in the external heat exchanger, and a superheat that supplies the fuel to the superheater in the external heat exchanger. A refueling fuel supply passage for supplying the fuel to the reheater in the external heat exchanger;
The circulating fluidized bed according to claim 3, wherein at least one of the evaporator fuel supply passage, the superheater fuel supply passage, and the reheater fuel supply passage has a control valve for adjusting the supply amount of the fuel. Combustion furnace plant.

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