前苏联专利SU1732821A3 Hybrid system of burning coal and coal dust in fluidized- bed

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专利摘要:
In a hybrid furnace system with fluidized bed and coal dust furnace, a fluidized bed furnace is located in lower part of the furnace body, a coal dust furnace is located above the fluidized bed furnace, and the furnace body for combustion of the rising fuel above the fluidized bed and the furnace body of the coal dust furnace are common. The section for the fluidized bed furnace, which contains a coal mill (10) without pneumatic deduster, a duct (12) connected to the coal mill (10) for recycling the exhaust gas, a duct (18 or 19) for coal supply, a coal charger (15) and air supply ducts (9, 16) for fluidization and combustion, is a furnace system independent of the operation of the coal dust furnace, while the section of the plant which serves as coal dust furnace, which contains a coal mill (1) with pneumatic deduster (25), a duct (5) which blows ground coal or coal dust prepared independently by the coal mill (1), at least one coal dust (6) and a duct (7) for the combustion air supply, is a furnace system independent of the operation of the fluidized bed furnace.
公开号:SU1732821A3
申请号:SU894614604
申请日:1989-07-14
公开日:1992-05-07
发明作者:Борошш Ласло；Ковач Шандор；Ременьи Пал Реш Карой；Вереш Ласло；Хорват Ференц；Герлан Тибор
申请人:Вилламошэнергиаипари Кутато Интезет, Татабаньаи Хоеремю (Инопредприятие)；
IPC主号:

专利说明:

The invention relates to a hybrid system for the combustion of coal dust in a fluidized bed, which, due to the combination of fluidized bed combustion and the usual combustion of coal dust, contains at least one charcoal burner, at least one coal mill (coal mill), one an air diffuser necessary for the combustion in the fluidized bed, a device for injecting secondary air, a device for slag removal, as well as a pilot device, and also concerns the method of transfer Ode to already existing pulverized coal boilers for a system for burning coal dust in a fluidized bed.
Coal dust combustion systems are known in which milled in a dust preparation system to the required fineness and dried coal dust is supplied to a dust-water heater, where the coal dust is mixed with combustion air. The mixture ignites in the furnace and burns at high temperature. A part of the released amount of heat is radiated to the cooled wall of the furnace, while the remaining part is used on the remaining surfaces of the boiler (superheater, feedwater heater, air heater).
This known type of incineration and the installation used for its implementation have the following disadvantages. In order to almost completely burn the combustible part of the coal dust, the coal must be ground to the required fineness, which is associated with significant energy costs and costs, despite this measure, problems may arise with ignition and fire extinguishing if the coal quality is lower than planned. A possible partial load (without auxiliary combustion with gas or oil) is at least about 60-70% of the nominal load. Due to the high temperature in the furnace, the emission of environmentally harmful substances, in particular NOx, is very important, and
The main additive is not sufficiently effective for binding S02; therefore, it is necessary to carry out subsequent expensive purification of waste gases.
Fluid bed combustion systems are known in which unmilled coal, injected, for example, through an air distribution distributor, is burned
partially or completely at 750-9506С with the help of air supplied through the air distributor.
In this case, the grinding process is eliminated, during which
coal dust, thereby reducing grinding costs. The heated fluidized bed of a large mass provides insensitivity to changes in coal quality and at the same time is limited to the range of 750-950 ° C
combustion temperature also limits
NOx and S02 pollution.
However, the known method of application
fluid bed burning also
associated with certain disadvantages.
In one embodiment of the fluidized bed combustion, complete combustion of the coal is achieved and most of the heat released is recovered by
fluidized bed cooling surfaces. In another embodiment, the coal in the fluidized bed is only partially burned, after which the gases coming out of the fluidized bed are burned using air directed through the fluidized bed. Moreover, in most cases, the cooling surfaces immersed in the fluidized bed fall off.
In both cases, the flow rate of air supplied to maintain the state of turbulence, as well as improving the combustion process, is relatively low (on average below 4 m / s), and therefore it is necessary to calculate a large cross section of the fluidized bed relative to the direction of air flow. compared to size
coal dust combustion systems, in which the coal dust feed rate is on average not less than 15 m / s, i.e. Only a relatively small amount of heat can be generated on one unit of the air distributor, which causes a significant increase in size.
In order to at least partially eliminate the drawbacks and inconveniences of fluidized bed or conventional burning of coal dust, hybrid combustion systems have been developed, combining the two systems.
However, the known devices for carrying out this hybrid combustion do not allow the strong power control that is often necessary, and in addition, the same sensitivity to coal quality remains, since both combustion systems are serviced by the same coal milling and feeding system, even contains separate nodes.
In this device, the air-separator, which is connected to a coal mill, has a certain grain size, for example 1-3 mm, is relatively homogeneous and the coal fines that have been previously dried in a coal mill are not sent back to the coal mill for further grinding. the mechanical conveying device is fed to the fluidized bed formed at the bottom of the boiler furnace, while finely ground coal dust from the air separator passing through the air separator Erez conduit pulverized coal is directed to exiting the furnace in the pulverized coal burner. This solution uses such a coal mill or such an air separator, through which all the coal required by both systems passes.
The disadvantage of this solution is that the coal and the coal burned in the fluidized bed and the coal burned in the pulverized coal burner are constantly determined and both systems cannot work separately from each other.
Closest to the proposed is a hybrid fluidized bed combustion coal dust system containing a boiler furnace with a fluidized bed placed on the distributor duct grate connected by an coal distributor through the latter supply line to the fuel preparation system and connected through the said duct with supply line
of a fluidizing air equipped with a flow regulator, a pulverized coal burner installed in the exit section above the bed to form a zone after the afterburning of ash from the bed and burning coal dust, the burner being connected to a fuel preparation system including a feeder with an air separator connected to the flue gas recirculation pipe from the furnace.
The aim of the invention is to enable operation on various types of fuels and to expand control limits.
The goal is achieved by the fact that the hybrid system of coal and coal dust in a fluidized bed contains an additional fuel system for the fluidized bed, made autonomous from the fuel preparation system - a coal-burning burner, equipped with its feeder and mill without an air separator, connected with its own recirculation line of flue gases and coal supply respectively to the afterburning zone and layer, while the air distribution duct can be made in the form of separate air sections.
With hybrid combustion in the proposed system, carried out partially by ordinary burning of coal dust and partially burning in a fluidized bed, the amount of coal burned in a furnace can exceed many times the amount of coal that is maintained above the duct box grid in a turbulent state and is burned there.
When coal quality is low, problems do not arise either during ignition or unintentionally extinguishing the fire, since these problems are eliminated by stable fluidized bed combustion. The hybrid combustion plant can also work without additional combustion of gas or oil with a partial load of 30-40% . The temperature in the furnace is maintained within the normal range for burning coal dust or burning in a fluidized bed; therefore, a better result can be achieved compared to burning only coal dust. Under no circumstances should the flame of the pulverized burner come in contact with the opposite wall, as this may lead to the formation of slag. Therefore, it is advisable to choose a high fluidization rate in excess of 4 m / s and dilute
coal dust flame. Excess air when burned in a fluidized bed carried out with a large excess of air can be consumed by coal dust blown through pulverized coal from the burner at a speed of 15-25 m / s, while its secondary air is supplied in a smaller amount and at a lower speed or It is not supplied at all, a homogeneous temperature distribution in the furnace is combined with known elements that ensure internal circulation of gas or dust.
Regarding the addition of base additives to reduce the environmentally harmful emissions of SOa, conventional solutions can be applied.
Unlike the coal used for the part used for burning coal dust, the coal supplied for burning in the fluidized bed can vary in quality as well as in origin, which makes it possible to adapt the incinerator to the corresponding conditions.
At low loads, advantageously, a portion of the fluidized bed incinerator operates. The burning capacity of a part of a coal dust burning unit in a burner must be calculated to be greater than that for a fluidized bed. Accordingly, the width of the fluidized bed in most cases is less than the full width of the furnace space.
The advantage of this hybrid combustion system is that the fluidized bed combustion part of the installation can also work independently, i.e. without the burner located above the fluidized fluid that burns the coal dust. Part of the coal dust burner can also be operated independently by means of a burner, whereas fluidized bed combustion is completely disabled. The possibility of such independent work, one from another, increases the flexibility of the entire installation, due to which it can be adapted to the power required at a given moment and the quality of the coal.
Figure 1 is a diagram of a vertical incinerator; 2 shows a coal mill with an air separator, a section; in FIG. 3 — a coal mill without an air separator, a section; in Fig.4 - air distribution box of a fluidized bed furnace; figure 5 - spray boot device, the incision;
figure 6 - air distribution box of the furnace in the form of sections.
The installation (FIG. 1) contains a furnace 2 of the boiler, a coal mill 1 connected via a recirculation pipeline 3 for sucking the exhaust gases for drying and transporting the coal fed through the feeder 4. The coal mill 1 is designed to grind coal to the fineness required for burning coal dust and is equipped for this purpose with an air separator 25 (Fig. 2). The latter is intended to separate coal particles from the coal dust stream that are not ground to the desired fineness. The separated portion of the coal is returned to the refining process in the coal mill 1.
The mixture of air with flue gases and coal is passed through conduit 22 to the coal mill (Fig. 2). The coal mill 1 itself has a shock head 23 and a drive motor 24. A shock separator 25 is located above the shock head 23, the lower part of which is connected to the pipe 22 through a pipe 26 to return the coarse grinding coal separated in the air separator.
The coal dust supplied to the pulverized coal burners 6 can also be obtained without intermediate activation of the coal mill 1 from the source of coal dust operating independently of the boiler. After the coal mill 1, the mixture consisting of coal dust and gas is transported through the dust pipe 5 to at least one dust coal burner 6. The latter can be installed in any way, for example, as a ceiling burner, side burner or angle burner.
Air is also supplied to the pulverized coal burner 6 via line 7.
At the bottom of the furnace 2, an air distribution box 8 is installed for combustion in a fluidized bed. Fluidization air through pipe 9 is directed to duct 8, which can be divided into sections 28 (Fig. 6), which allows sector-controlled regulation of the velocity of the liquefying air. As a consequence, in the furnace 2, a favorable distribution of the waste gas flow can be achieved.
The coal in the fluidized bed 11 is fed through line 18 or when fed from the bottom through line 19 from the coal mill 10 or the crusher. The coal mill 10 or the coal crusher grinds the coal into conventional coarse particles for fluidized bed combustion, which for bed 11 should not be separated and returned back to the coal mill 10, therefore no air separator is installed in the latter. The coal mill 10 (FIG. 3) has a shock head 29, a drive motor 30, as well as a pipeline for coarse grinding and a mixture of air and flue gases.
The coal mill 10 also sucks off the exhaust gas from the furnace 2 through the recirculation line 12, into which unground coal is fed through the feeder 13. After the coal mill 10, the mixture of coal dust and gas can be supplied from pipe 14 either via line 18 above layer 11 to furnace 2, or when feeding fluidized bed 11 from below along line 19 through duct 8 under fluidized bed 11. Air is fed through 18 or via pipeline 27 (FIG. 4 and 6).
The loading of the fluidized bed 11 can also occur by means of a spray dispenser 15 (FIG. 5). Coal in this case with the required particle size is sprayed onto the fluidized bed 11. Unbroken charcoal through pipeline 32 gets onto the rapidly rotating disk 31, which sprays the coal onto the fluidized bed 11. Line 18 feeding coarse grinding from a coal mill 10 without air the separator on the fluidized bed 11, during operation of the spray loading device 15 does not work. In the case of line 18 operation, the spray dispenser 15 stops,
In all these embodiments, air is supplied through conduit 16 in such an amount that, together with the air supply through conduit 7, is necessary for complete combustion of the mixture of gas and flue gases coming out of the fluidized space and oxygen supplied through a dust pipe 5. in the mixture of gas and flue gases leaving the fluidized bed 11 is set to the usual value (2-10%), the temperature of the fluidized bed 11 is set by controlling the amount of fluidizing air Ha.
The additive binding the contaminated S02 is fed through conduit 20 and / or conduit 21.
The non-combustible solid substance remaining in the furnace 2 after burning is removed from it through a conduit 17 passing through the duct 8 to remove slag.
If the fluidized bed part of the hybrid combustion system is to be operated separately, i.e. out of work serving to burn coal
dust parts, the 4 coal feeder and coal mill 1 do not work. No coal dust is blown through the dust pipe 5, while the feeder 13, the mill 10 and / or the spray
the loading device 15 feeds a portion to be burned in a fluidized bed. However, if it is required to maintain in operation a part for burning coal dust, without putting into operation outside the part for burning in the fluidized bed, the coal mill 1 and the dust pipe 5 work, and the feeder 13. coal mill 10 and / or the spray charging device 15, as well as the pipeline 9 is stopped up.
The proposed installation allows combining the burning of coal dust and fluidized bed burning while eliminating the disadvantages
0 of these combustion methods.
The advantage of the proposed hybrid system is that even with poor coal quality, stable combustion can be ensured, as well as with a partial load of 30-40%, while the amount of heat released in the furnace is not limited at all by the air-spray box. In addition, good environmental performance is achieved.
0 Wednesday
These advantages are also achieved by converting existing pulverized coal fired boilers to a hybrid combustion system. Translation originally done for
5, the combustion of coal dust from boilers for hybrid combustion can be carried out in such a way that an air separator is removed from the part used to produce fine coal dust of already known coal mills, as a result of which coal mill 1 is converted into coal mill 10 without an air separator. The bed for the fluidized bed, made in place of the lower funnel of the boiler, is loaded
5 by coarse grinding of these modified coal mills 10. Under the fluidized bed 11, an air distribution box 8 is installed to supply air to the layer 11. Other coal mines used in the production of fine coal dust, as well as dust-free burners, can remain unchanged.
Such modification of the boiler especially
5 is preferable if the quality of the coal burned in the boiler varies, deteriorates and it is impossible to ensure stable operation of the best coal calculated for the combustion of the boiler with the originally installed system for burning coal dust.

权利要求:
Claims (2)
[1]
1. Hybrid combustion system of coal and coal dust in a fluidized bed, containing the furnace of a fluidized bed boiler placed on the grille of the distribution box connected by a coal distributor through the feed line of the latter to the fuel injection system and connected to the liquefying supply pipe through the said duct air, equipped with a flow regulator, pulverized coal burner installed outlet section above the layer
to form directly after the last zone of afterburning of the ash from the bed and burning coal dust, the burner being connected with its dust pipe to the system
, fuel preparation, including a feeder, a mill with an air separator, connected to the flue gas recirculation pipeline from the furnace, characterized in that
the ability to work on different types of fuel and to expand the limits of regulation, it contains an additional system of fuel preparation of the fluidized bed, made autonomous from
a pulverized coal burner fuel preparation system equipped with its own feeder and mill without an air separator connected with its flue gas recirculation and coal supply lines, respectively, to the afterburning zone and to the layer.
[2]
2. The system according to claim 1, characterized in that the air distribution duct is made in the form of separate air-regulated sections.
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同族专利:

公开号 | 公开日

GB2239697B|1992-07-08|

US4993332A|1991-02-19|

CS708588A3|1992-02-19|

HU201230B|1990-10-28|

UA19066A|1997-12-25|

AT400072B|1995-09-25|

CZ278704B6|1994-05-18|

DD276519A1|1990-02-28|

ATA901488A|1995-01-15|

HUT48104A|1989-05-29|

GB8916131D0|1989-09-20|

GB2239697A|1991-07-10|

SK278148B6|1996-02-07|

WO1989004940A1|1989-06-01|

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法律状态:

优先权:

申请号 | 申请日 | 专利标题

HU874645A|HU201230B|1987-11-17|1987-11-17|Acaricides with synergetic effect and comprising thiophosphoryl glycineamide derivative as active ingredient|LV930672A| LV5637A3|1987-11-17|1993-06-28|Hybrid system oglu and oglu dirt burning pseudo-pseudo-slani|

LTRP906A| LT2297B|1987-11-17|1993-08-30|HYDROCARBON SYSTEM COMBUSTION WITH CARBON OR CARBON DETERGENT IN LIQUID LAYER|

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