KR200249592Y1 - A nozzle with one air ejecting hole in the circulating fluidized bed - Google Patents

Abstract

The present invention relates to a dispersion nozzle having one air outlet in a circulating fluidized bed, and its purpose is to produce ash produced during combustion in a dispersion nozzle planted in a dispersion plate for supporting bed material and injecting fluidized air in a circulating fluidized bed boiler for cogeneration and power generation. And a dispersion nozzle with one air outlet in a circulating fluidized bed which prevents the combustion material from flowing back through the nozzle and gives direct air flow to reduce ash, and reduces the pressure applied to the dispersion plate having the dispersion nozzle. In providing.

The present invention in the dispersion nozzle (4) planted in the dispersion plate (3) of the circulation fluidized bed boiler,

The dispersion nozzle 4 has a tubular nozzle head 8 having a circular hole and one air outlet 10, and the nozzle rod 7 is inserted into the circular hole at a right angle with the nozzle head 8. It is to be provided that the area Ad _ep of the air jet port 10 is made larger than the area A _di of the air jet port to reduce the pressure applied to the dispersion nozzle 4.

Description

A nozzle with one air ejecting hole in the circulating fluidized bed

The present invention relates to a dispersion nozzle having one air outlet in a circulating fluidized bed, and more particularly, a nozzle of a distribution plate for injecting fluidized air in a circulating fluidized bed boiler for cogeneration and power generation. Fluidized fluid, prevents ash and combustion materials generated during combustion from flowing back through the nozzle, and circulates the fluidized bed to ease the discharge of ash by directing the flow of air, and to reduce the pressure applied to the dispersion plate having the dispersion nozzles. The present invention relates to a dispersion nozzle having one air outlet.

In general, fluidized bed combustion technology has a wide acceptance capacity for fuel, ease of furnace desulfurization and dehalogenation, easy control of furnace temperature, and incineration at relatively low temperatures, resulting in small nitrogenous products and excellent fuel mixing in the incinerator. It has the advantage of being mixed with other fuels, and has been applied to cogeneration and power generation boilers that produce steam for power generation, process, and district heating by using high-temperature heat obtained by burning fossil fuels such as coal.

3 shows an example of a circulating fluidized bed boiler for burning fossil fuel such as coal. It consists of a combustion chamber 1, a fluidized bed 2 through which a fluid medium flows, a dispersion plate 3, a dispersion nozzle 4, and an air box 5 into which fluidized air is injected. 2 shows an example of a conventional dispersion nozzle for a circulating fluidized bed boiler, which forms an 'a' shape so that air is ejected in one direction from the dispersion nozzle, and an angle formed by the nozzle rod and the nozzle head is 82 °. In addition, the diameter (d _i ) of the nozzle rod is 29.5 mm, while the diameter (d _ep ) of the air nozzle of the nozzle head is 27.2 mm, and the air outlet of the nozzle head is smaller than the nozzle rod.

In the fluidized bed incinerator using the conventional dispersion nozzle configured as described above, the ash is easily discharged by directing the flow of air without falling into the air box, but the operating flow rate of the circulating fluidized bed boiler is 2.2 at 900 ° C. ~ 3.5㎧) implies an excessive pressure.

In order to solve the above problems of the present invention, more specifically, as a dispersion nozzle of a dispersion plate for injecting fluidized air in a circulating fluidized bed boiler for cogeneration and power generation, the fluidized air is evenly sprayed into the bed to form a layer. A circulating fluidized bed which fluidizes, prevents ash and combustion materials generated during combustion from flowing back through the dispersion nozzles, and facilitates ash discharge by directing the flow of air, and reduces the pressure applied to the dispersion plate in which the dispersion nozzles are planted. In order to provide a dispersion nozzle having one air outlet in the.

1 is a spray nozzle having a single air outlet of the present invention

2 is a block diagram of a conventional dispersion nozzle

3 is a schematic diagram of a circulating fluidized bed boiler

<Description of Symbols for Main Parts of Drawings>

(1) combustion chamber (2) fluidized bed

(3) Dispersion Plate (4) Dispersion Nozzle

(5) air box (6) exhaust pipe

(7) Nozzle Bar (8) Nozzle Head

(9) Air inlet (10) Air outlet

(11) refractory

If described in detail in connection with the accompanying drawings the configuration and the operation of the embodiment of the present invention to achieve the object as described above and to perform the task for removing the conventional drawbacks.

1 is a dispersion nozzle having an air outlet of the present invention, FIG. 2 is a configuration diagram of a conventional dispersion nozzle, and FIG. 3 is a schematic view of a circulating fluidized bed boiler, and the present invention is a circulating fluidized bed boiler as shown in FIG. 1. In the dispersion nozzle (4) planted in the dispersion plate (3), the dispersion nozzle (4) has a tubular nozzle head (8) having a circular hole and one air outlet (10) and the circular hole. The nozzle rod 7 is inserted and installed so as to be perpendicular to the nozzle head 8, and the area AD _ep of the air outlet 10 is configured to be larger than the area A _di of the air inlet 10 to distribute the nozzles. Dispersion nozzles with one air outlet in the circulating fluidized bed are equal to the number of dispersion nozzles planted in the distribution plate of the circulating fluidized bed boiler. It depends on the area of the spout. Therefore, when the pressure applied to the dispersion plate is excessive at the operating flow rate of the circulating fluidized bed reactor, it is possible to reduce the excessive pressure by increasing the area of the air outlet of the dispersion nozzle. At this time, if the area of the air outlet (A _dep ) is larger than the area of the air inlet (A _di ), the main pressure applied to the dispersion nozzle is subject to the area of the air inlet. Therefore, the function of the existing dispersion nozzle (uniform fluidization) To lower the pressure applied to the dispersion nozzle while maintaining the proper orifice flow rate without maintaining the proper orifice flow rate through the nozzle. As a means, the air outlet is made larger than the air inlet. The operation of the present invention configured as described above provides fluidization air from the high pressure air box to the low pressure air inlet 9 and is provided in one direction of the nozzle head 8. The air is blown into the bed through the air outlet 10. This blown air is continuously blown out and fluidized, forming a directional jet. This causes the main pressure increase of the dispersion nozzle to flow in the nozzle rod 7 to lower the pressure increase at the air outlet 10 of the nozzle head 8, and to adjust the flow rate of air at the air outlet 10 to the proper flow rate range. To stay inside.

32 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.

Dispersion nozzles having one air outlet in the circulating fluidized bed of the present invention constructed and functioned as described above induce uniform fluidization without dead zones in the entire area of the distribution plate, and cause local obstruction or analogy by clogging of the nozzle. It is a useful design that prevents assimilation and prevents backflow of the fluidized medium into the air box by maintaining the proper air ejection flow rate in the operating flow rate range of the circulating fluidized bed boiler.

Claims (3)

In the dispersion nozzle (4) planted in the dispersion plate (3) of the circulating fluidized bed boiler, The dispersion nozzle 4 has a tubular nozzle head 8 having a circular hole and one air outlet 10, and the nozzle rod 7 is inserted into the circular hole at a right angle with the nozzle head 8. Dispersion nozzle with one air outlet in the circulating fluidized bed, characterized in that installed The method of claim 1, Dispersion having one air outlet in the circulating fluidized bed, characterized in that the total area Ad _ep of the air outlet 10 is larger than the area A _di of the air inlet, thereby reducing the pressure applied to the dispersion nozzle 4. Nozzle. delete