KR20040080681A - Temperature Control apparatus and Control method at the combustor exit in a circulating fluidized bed combustion system - Google Patents

Abstract

PURPOSE: A circulation fluidized-bed combustion system having a temperature control apparatus at a combustor exit and a method for controlling the temperature of the combustor exit are provided to prevent the thermal efficiency of a boiler from lowering. CONSTITUTION: In a circulation fluidized-bed combustion system, a smoke stack(7) is connected to a dust collecting unit(4). A suction fan(9) is installed at a connecting passage(10) for discharging exhaust gas to the smoke stack. The exhaust gas sucked by the suction fan is circulated in a combustor exit.

Description

Temporary control apparatus and control method at the combustor exit in a circulating fluidized bed combustion system

The present invention relates to a circulating fluidized bed combustor having a combustion furnace outlet temperature control device and a method for controlling the temperature of a combustion furnace outlet, comprising: a circulating fluidized bed combustion device consisting of a combustion furnace, a cyclone, a particle circulation unit, a convection heat transfer unit, a dust collector, and a stack Part of the exhaust gas discharged through the stack is refluxed to the exit of the combustion furnace or the rear end of the cyclone, and the temperature is raised above the appropriate level at the exit of the combustion furnace and the rear end of the cyclone by post combustion of unburned carbon powder and unburned gas. The present invention relates to a combustion furnace outlet temperature control device and a temperature control method capable of preventing the same.

Circulating fluidized bed boilers can be applied to various fuels with high combustion efficiency, nitrogen oxide production suppression effect according to combustion temperature of 800 ~ 950 ℃, sulfur oxide emission control through limestone input, and thermal inertia of bed particles. Because of its capacity for fluctuations, it is expanding its application to not only coal boilers but also various industrial wastes and municipal waste incineration.

Currently in Korea, a circulating fluidized bed that uses coal or refinery coke as a fuel has been supplied since the mid-1980s, and dozens are in operation or planned for construction.

The configuration of such a circulating fluidized bed combustion apparatus will be described with reference to FIG. 2, a fuel storage tank 108 for storing fuel, a combustion furnace 101 for burning fuel injected from the fuel storage passage 108, and the combustion. Cyclone 102 for trapping particles exiting the combustion furnace 101 by being entrained together with combustion air supplied to the furnace 101, and reinjecting the particles collected in the cyclone 102 into the lower part of the combustion furnace Particle circulation section 105, convection heat transfer section 103 for recovering the sensible heat of the exhaust gas from which the particles are separated in the cyclone 102, and dust collecting to collect fine scattering particles not collected in the cyclone 102 A facility 104 and a stack 107 for discharging the exhaust gas passed through the dust collector 104 to the outside.

Looking at the process of the circulating fluidized bed combustion apparatus configured as described above, the fuel stored in the fuel reservoir is supplied to the lower portion of the combustion furnace, wherein the primary air for combustion (A1) is supplied to the lower portion of the combustion furnace filled with the layer material having an average particle diameter of about 300㎛. The fuel introduced into the combustion furnace is combusted, and the combustion gas generated by the combustion of the fuel is discharged to the exit of the combustion furnace, while the entrained particles in the combustion furnace are collected in the cyclone, and the high pressure at the lower end of the cyclone is low. The pressure is maintained in the particle circulation so that the particles collected to the bottom of the combustion can be circulated by the particle circulation supply air (A3), the combustion gas separated particles in the cyclone is sensible heat in the sensible heat in the convection heat transfer The fine fugitives which are not collected in the cyclone are collected in the dust collector and the remaining exhaust gas is discharged to the atmosphere through the stack. It was configured to be.

On the other hand, the area fluidized by the primary air for combustion introduced from the lower part of the combustion furnace is a reducing atmosphere in which partial combustion proceeds, and the unburned gas and carbon are injected due to the injection of the secondary air (A2) having a high particle density and located above the fuel inlet. Combustion of particles proceeds more and more, and as the upper part rises, the particle density decreases and maintains a substantially constant value above a certain height, and these groups of particles exit the combustion furnace containing layer materials such as unburned carbon, ash, and desulfurization agent. Will go out.

In general, coal fuel having a particle diameter of 12 to 20 mm or less is introduced from the bottom of the circulating fluidized bed combustion furnace. In the case of containing a large amount of fine particles or increasing the supply amount of primary air for combustion, carbon particles entrained to the upper part of the bed are added. As the amount of unburned fuel is also increased and the post-combustion progresses, the temperature may rise above the appropriate level from the furnace exit to the cyclone and the inlet of the convective heat transfer part, especially when the furnace temperature is operated above 900 ° C. After combustion of the carbon powder and the unburned gas, a problem arises in that the temperature rises above an appropriate level in the portion.

That is, when the temperature rises above 950 ° C. near the furnace exit, slag may occur on the furnace wall and the boiler tube 109 due to ash, or deposition may occur due to convection heat exchanger ash melting. This can reduce the efficiency or even stop the operation, and the desulfurization efficiency due to the temperature rise is also drastically lowered, so that a large amount of desulfurization absorber is introduced or the concentration of sulfur oxides is increased.

The layer particles maintained at a high temperature in the cyclone are introduced into the particle circulation as they are, or the temperature is further increased by the combustion of unburned carbon therein, whereby the layer material is agglomerated in the high temperature state to the circulation of the particles. This can be an obstacle and eventually a driving obstacle.

On the other hand, as a method of preventing the temperature rise of the cyclone, a method of installing a water pipe for heat exchange or a pipe for injecting cooling air may be considered at the wall of the cyclone portion at the exit of the combustion furnace. The inherent problem is that inherent combustion does not provide a means of solving the fundamental problem of suppression of temperature rise at the exit of the combustion furnace by post-combustion and the injection of cooling air causes a problem of lowering combustion efficiency.

The present invention is devised to solve the conventional problems as described above, the object of the combustion is a large amount of fine particles in the fuel injected into the combustion furnace or the amount of post-burning by the unburned fuel according to the change in operating conditions When the temperature rises above the proper level after the exit of the furnace, it controls the problems such as slagging and fouling due to the temperature rise, and prevents the boiler's thermal efficiency from being reduced by external air input and achieves a stable cooling effect. The present invention provides a circulating fluidized bed combustion device having a combustion furnace outlet temperature control device and a combustion furnace outlet temperature control method.

1 is an exemplary view showing the configuration of a circulating fluidized bed combustion apparatus according to the present invention

Figure 2 is an exemplary view showing the configuration of a conventional circulating fluidized bed combustion apparatus

<Description of the symbols for the main parts of the drawings>

(A1): Primary air for combustion (A2): Secondary air for combustion

(A3): air for particle circulation supply (W): water

(1) (101): combustion furnace (2) (102): cyclone

(3) (103): Convection heat circulation section (4) (104): Dust collection equipment

(5) (105): Particle circulation part (6) (106): Induced blower

(7) (107): stack (8) (108): fuel reservoir

(9): suction blower (10): connector

109: boiler tube

The present invention which achieves the object as described above and the problem to eliminate the conventional drawbacks is a fuel reservoir (8) for storing fuel and a combustion furnace (1) in which the combustion of fuel injected from the fuel reservoir (8) is made ), A cyclone (2) for trapping particles exiting the combustion furnace by entraining with the combustion air supplied to the combustion furnace (1), and the particles collected in the cyclone (2) to the combustion furnace (1). ) Particle circulation part 5 to be re-injected to the lower part, convection heat transfer part 3 for recovering sensible heat of exhaust gas from which particles are separated in the cyclone 2, and fine scattering not collected in the cyclone 3 In the circulating fluidized bed combustor composed of a dust collecting device (4) for collecting particles and a stack (7) for discharging exhaust gas through the dust collecting device (4) to the outside, the dust collecting device (4) and the stack (7) are Connect the flue gas passed through the dust collector to the stack A suction blower (9) is connected and installed on the connecting pipe line (10) to transmit, and the exhaust gas sucked through the suction blower (9) is returned to a selected portion of an outlet of a combustion furnace, a cyclone inlet or an outlet side. A circulating fluidized bed combustion device having a configured combustion furnace outlet temperature control device,

A fuel reservoir (8) for supplying fuel containing fine particles, a combustion furnace (1) for forming a fluidized bed by combustion air, a cyclone (2) for collecting particles exiting the combustion furnace, and Particle circulation section 5 for recirculating the particles to the combustion furnace 1, convection heat transfer section 3 for recovering sensible heat of the combustion gas, dust collecting facility 4 for collecting fly ash, and exhaust gas to the atmosphere In controlling the combustion furnace outlet temperature of the circulating fluidized bed combustor composed of stacks (7), the part of the exhaust gas passing through the dust collector is refluxed to the selected one of the furnace outlet or the cyclone inlet or outlet side to control the temperature. Outlet temperature control method in the circulating fluidized bed combustor.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows an exemplary view showing the configuration of the circulating fluidized bed combustion apparatus according to the present invention, the present invention is a high temperature including unburned carbon and unburned gas when the temperature rises in the combustion furnace (1) outlet or cyclone (2) It was configured to control the outlet temperature of the combustion furnace by partially refluxing the outlet gas of the combustion furnace and the low temperature exhaust gas discharged to the stack 7 and mixing it with the high temperature combustion gas.

As the unburned carbon and unburned gas enter the cyclone (2) through the upper end of the combustion furnace (1), the temperature of the combustion gas is increased by the post-combustion depending on the amount of fuel supplied, its characteristics, particle size distribution, and air flow rate. For example, when the outlet temperature of the cyclone is 950 ° C, 5 to 8% of the exhaust gas having a temperature value of 200 ° C exiting the stack is refluxed using a suction blower to the inlet or outlet of the combustion furnace or the cyclone. When injected by injecting, the temperature of 885 ~ 915 ° C was shown to be able to maintain a stable temperature range.

Here, if the reflux ratio of the exhaust gas is 4% or less, the effect of temperature drop in the cyclone is not obvious. If the reflux ratio is 9% or more, the pressure drop increases due to the increase in the flow rate of the cyclone inlet and the heat exchange due to the temperature drop of the convection heat transfer inlet. As the size of the equipment increases as the efficiency decreases and the flow rate increases, the reflux ratio of the exhaust gas is preferably 5 to 8%.

The injection position of the reflux flue gas is configured to reflux the flue gas by connecting the suction blower 9 to one selected from the combustion furnace outlet, the cyclone inlet or the outlet side, that is, the temperature increase suppression, and the cyclone outlet side. The method of injecting flue gas is useful for suppressing the temperature rise at the inlet of the convective heat transfer unit without degrading the cyclone efficiency.In consideration of the residence time and the mixing of the combustion gas and the reflux flue gas, it is preferable to inject the reflux flue gas at the exit of the combustion furnace. Preferably, it is difficult to apply in the case of a circulating fluidized bed combustor that is already installed and operated, and injecting reflux flue gas into the cyclone inlet side can be applied to both the circulating fluidized bed combustor that is already installed and operated or newly manufactured, Configured to return the exhaust gas to the combustion furnace outlet or cyclone inlet side If there is an advantage of easy installation and maintenance of the reflux duct not shown.

As described above, the present invention provides a part of the exhaust gas of 200 ° C. or less, oxygen concentration of 4% or less, and a large heat capacity value returned through the dust collection unit to the combustion furnace outlet or the cyclone inlet or outlet side, thereby producing a high temperature combustion gas and a reflux flue gas having a relatively low temperature. By forced mixing, the temperature of the inlet and outlet side of the combustion furnace exit and cyclone can be controlled. When the temperature rises above 900 ° C near the cyclone, CaSO ₄ is more decomposed at higher temperatures than the sulfur oxide removal rate by the sulfur oxide absorbent. As a result, the reaction for releasing SO ₂ proceeds more actively to prevent the increase in sulfur oxide emission concentration and the consumption of sulfur oxide absorbent due to the desulfurization efficiency decrease.

In the drawings, reference numeral W denotes water.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

As described above, the present invention is configured to return a part of the exhaust gas to a selected one of the inlet or the outlet side of the combustion furnace outlet or the cyclone to maintain the thermal efficiency of the boiler by refluxing the exhaust gas without using external air, By maintaining the proper temperature level at the combustion furnace outlet and the inlet and outlet of the cyclone, it is possible not only to prevent ash slagging on the furnace wall or the heat recovery tube, but also to prevent fusion and fouling by ash in the convection heat transfer part. In addition, the temperature of the particles flowing into the particle circulation is also maintained at an appropriate level to prevent high temperature aggregation of the layer material by combustion, and to suppress the increase in sulfur oxide emission concentration to reduce the consumption of sulfur oxide absorbent, etc. Is there.

Claims (3)

A fuel storage tank for storing fuel, a combustion furnace where combustion of fuel injected from the fuel storage tank is performed, a cyclone for collecting particles exiting the combustion furnace with the combustion air supplied to the combustion furnace, and A particle circulation unit for reinjecting the particles collected in the cyclone into the lower part of the combustion furnace, a convection heat transfer unit for recovering the sensible heat of the exhaust gas from which the particles are separated in the cyclone, and fine scattering particles not collected in the cyclone unit In the circulating fluidized bed combustion device composed of a dust collector and a stack for discharging exhaust gas through the dust collector to the outside, The suction blower is connected to the dust collector and the stack to connect the suction blower to the stack to transfer the exhaust gas through the dust collector to the stack, and the exhaust gas sucked through the suction blower is selected from the outlet, the cyclone inlet, or the outlet of the combustion furnace. Circulating fluidized bed combustion device having a combustion furnace outlet temperature control device, characterized in that it is configured to reflux to one part. A fuel reservoir for supplying fuel containing fine particles, a combustion furnace for forming a fluidized bed by combustion air, a cyclone for collecting particles exiting the combustion furnace, and a particle circulation for recycling the collected particles to the combustion furnace In controlling the combustion furnace outlet temperature of the circulating fluidized bed combustor comprising a part, a convective heat transfer part for recovering sensible heat of the combustion gas, a dust collecting facility for collecting fly ash, and a stack for exhausting exhaust gas to the atmosphere, And controlling the temperature by refluxing a part of the exhaust gas that has passed through the dust collector to a selected one of a combustion furnace outlet, a cyclone inlet, or an outlet side to control the temperature. The method of claim 2, Combustion furnace outlet temperature control method in the circulating fluidized bed combustion apparatus, characterized in that the reflux ratio of the reflux flue gas is 5 ~ 8%