KR101033941B1 - Device for exhausting fly ash - Google Patents

Abstract

The present invention is a storage tank for storing the fly ash (fly ash) generated in the boiler and the air to move the fly ash; An unloading chute for discharging the fly ash stored in the reservoir to the outside for recycling; A chute outlet pipe connecting the unloading chute and the reservoir to provide a path for moving a portion of the fly ash to the reservoir; And an air ejector for supplying air to the chute outlet pipe to move the fly ash to the reservoir along the chute outlet pipe. Such a fly ash discharge device reduces the blockage of the device and the resulting malfunctions, and reduces the costs associated with installation and maintenance.

Fly ash, air ejector, air nozzle

Description

Fly Ash Discharge Device {DEVICE FOR EXHAUSTING FLY ASH}

The present invention relates to a device for treating fly ash generated from a boiler, and more particularly, to a fly ash discharge device for discharging fly ash to be recycled.

In general, coal-fired power plants generate various wastes through the combustion process. In particular, a fly ash is generated in a boiler for burning pulverized coal. Fly ash is economical by mixing 20 to 30% of cement with improved workability and relieving heat of cure and long term strength and water tightness. Because of this, the fly ash can be used as admixture of concrete. In order to use fly ash as a concrete admixture, the following fly ash discharge device is used.

1 is a view showing a fly ash discharge device 200 according to the prior art. In general, the fly ash is stored in the reservoir 201 together with air generated from the boiler to move it. The reservoir 201 is a space that is stored before the fly ash is taken out to be recycled. The fly ash stored in the reservoir 201 is loaded into a bulk car for carrying out the fly ash to the outside using an unloading chute 202 in the form of a flexible hose. On the other hand, in the process of loading the fly ash using the unloading chute 202, a portion of the fly ash is blown by the influence of air. If the fly ash is not collected, a large amount of fly ash may leak out, causing environmental pollution. The flying fly ash goes through the capture process. This fly ash must be collected by a chute vent filter 204. First, the fly ash moves to the chute outlet filter 204 through the chute outlet pipe 203. The fly ash that has moved to the chute outlet filter 204 is subjected to the action of a chute vent fan 206. The chute outlet fan 206 discharges air to the outside through the chute outlet filter 204, but the fly ash is collected by the chute outlet filter 204 and collected in the chute outlet filter 204 without being discharged to the outside. As a result, the fly ash is separated from the air. The fly ash collected by the chute outlet filter 204 is moved back to the reservoir 201 via a vent filter house 205.

Repeating the above process using the fly ash discharge device, the chute exit pipe and the outlet filter house is clogged due to changes in the moisture content of the fly ash and the internal environment of the fly ash discharge device. In particular, the summer rainy season occurs more frequently. Thus, there is a problem that a malfunction of the fly ash discharge device occurs. In addition, the operator and the maintenance personnel participate in removing the blockage, causing a waste of cost, time, and manpower.

The present invention is to provide a fly ash discharge device to reduce the clogging caused by the fly ash to reduce the malfunction.

In addition, the present invention is to provide a fly ash discharge device that can simplify the installation and thereby reduce the installation and maintenance costs.

In addition, the present invention is to provide a fly ash discharge device that can reduce the fly phenomenon of fly ash.

The present invention is a storage tank for storing the fly ash (fly ash) generated in the boiler and the air to move the fly ash; An unloading chute for discharging the fly ash stored in the reservoir to the outside for recycling; A chute outlet pipe connecting the unloading chute and the reservoir to provide a path for moving a portion of the fly ash to the reservoir; And an air ejector for supplying air to the chute outlet pipe to move the fly ash to the reservoir along the chute outlet pipe, wherein the air ejector is air for supplying the chute outlet pipe. Is stored, the air header (air header) for adjusting the air supply amount (air header); An air hose providing a path for the air supplied from the air header to move to the chute outlet pipe; And an air nozzle installed on an outer circumferential surface of the chute outlet pipe and connecting the air header to the chute outlet pipe to guide air passing through the air hose to the chute outlet pipe. A fly ash discharge device is disclosed.

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In addition, the air hose is installed at both ends, it discloses a fly ash discharge device characterized in that it comprises quick couplings for connecting the air hose to the air nozzle and the air header.

The fly ash discharge device according to the invention comprises a reservoir, an unloading chute, chute outlet piping and an air ejector. In particular, the air ejector prevents fly ash from accumulating in the chute outlet pipe due to the air supply to the chute outlet pipe, thereby reducing clogging and reducing the malfunction of the fly ash discharge device. In addition, the air ejector simplifies the configuration of the fly ash discharge system, reducing the cost of installation and maintenance. In addition, the fly ash is circulated inside the reservoir and the chute outlet pipe is not discharged to the outside.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, if it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

2 is a view showing a fly ash discharge device 100 according to a preferred embodiment of the present invention, Figure 3 is a chute outlet pipe 103 and the air ejector of the fly ash discharge device 100 shown in FIG. FIG. is a view schematically illustrating the connected state of the ejector 104. As shown in Figure 2 and 3, the fly ash discharge device 100 according to a preferred embodiment of the present invention is a reservoir 101, unloading chute 102, chute outlet pipe 103 and air ejector 104 It includes.

Storage tank 101 stores the fly ash generated in the boiler, and the air to move the fly ash. The fly ash moves downward gradually under the influence of gravity within the reservoir 101. This causes the fly ash to reach the loading chute 102 under the influence of gravity.

The unloading chute 102 is manufactured in the form of a flexible hose and discharged to the outside for recycling the stored fly ash. The fly ash discharged through the unloading chute 102 is loaded into the bulk car. In addition, the bulk car moves to a place for loading and recycling fly ash. On the other hand, in the process of the fly ash is discharged by the unloading chute 102 is a phenomenon that some of the fly ash is blown out.

The chute outlet pipe 103 connects the reservoir 101 and the unloading chute 102 to provide a path for moving the fly ash to the reservoir 101 when the fly ash is discharged from the unloading chute 102 to the outside. . Therefore, the fly ash blowing from the unloading chute 102 acts on the air inside the reservoir 101 and flows into the chute outlet pipe 103.

The air ejector 104 is connected to the chute outlet pipe 103 to supply air to the chute outlet pipe 103. At this time, air is supplied through the outer circumferential surface of the chute outlet pipe 103. As a result, the fly ash introduced into the chute outlet pipe 103 moves toward the storage tank 101 along the chute outlet pipe 103. In addition, the air ejector 104 includes an air header 141, an air hose 143, an air nozzle 144, and a quick coupling 145.

The air header 141 may store air for supplying the chute outlet pipe 103, and may adjust the air supply amount.

The air hose 143 is a flexible hose, which connects the air header 141 and the air nozzle 144 so that the air supplied from the air header 141 moves to the chute outlet pipe 103. To provide. In addition, since the air hose 143 has flexibility, it may be arranged in various forms.

At least one air nozzle 144 is provided on an outer circumferential surface of the chute outlet pipe 103, and connects the air header 141 to the chute outlet pipe 103. As a result, the air nozzle 144, in combination with the air hose 143, serves as a path through which the air stored in the air header 141 passes through the air hose 143 to the chute outlet pipe 103. In addition, it also serves to determine the performance of the air ejector 104.

In this embodiment, the air nozzle 144 is installed every 90 degrees along the circumferential direction of the chute outlet pipe 103, and four air nozzles 144 are shown installed in the chute outlet pipe 103. However, the present invention is not limited thereto, and the number of air nozzles 144 to be used may be selected in consideration of the situation and cost of the site.

The larger the diameter of the air nozzle 144, the more air can be supplied. For example, when comparing the air nozzle 144 having a diameter of 5 mm and the air nozzle 144 having a diameter of 3 mm, the air nozzle 143 having a diameter of 5 mm has a diameter of 3 mm. It is possible to supply a larger amount of air than the air nozzle 144. In addition, when comparing two air nozzles 144 having a diameter of 3 mm and one air nozzle 144 having a diameter of 5 mm, there are more air nozzles 144 having a diameter of two 3 mm. The amount of air can be supplied. Therefore, the diameter of the air nozzle 144 is preferably determined in consideration of the length of the chute outlet pipe 103, site requirements, cost, and the like.

In addition, the air nozzle 144 is inclined in the direction of the storage tank 101 from the chute outlet pipe 103 to form a constant angle with the chute outlet pipe 103. This angle depends on the chute outlet tubing 103 size.

The quick coupling 145 is installed at both ends of the air hose 143, and used to connect the air hose 143 to the air nozzle 144 and the air header 141, and easily maintains a solid connection. It can be detached.

On the other hand, the air ejector 104 prevents the fly ash from accumulating inside the chute outlet pipe 103 to supply air to the middle of the chute outlet pipe 103. Above all, the air ejector 104 replaces the chute outlet filter 204, the vent filter house 205 and the chute outlet fan 206 in the prior art, where clogging occurs, and the fly ash reservoir 101. Move to).

While specific embodiments have been described above, it will be apparent to those skilled in the art that various modifications may be made without departing from the scope of the present invention.

1 is a view showing a fly ash discharge device according to the prior art.

2 is a view showing a fly ash discharge device according to a preferred embodiment of the present invention.

FIG. 3 is a view schematically illustrating a state in which the chute outlet pipe and the air ejector of the fly ash discharge device illustrated in FIG. 2 are connected.

Claims (3)

delete A storage tank for storing fly ash generated in a boiler and air for moving the fly ash; An unloading chute for discharging the fly ash stored in the reservoir to the outside for recycling; A chute outlet pipe connecting the unloading chute and the reservoir to provide a path for moving a portion of the fly ash to the reservoir; And An air ejector for supplying air to the chute outlet pipe to move the fly ash to the reservoir along the chute outlet pipe, The air ejector, An air header in which air for supplying the chute outlet pipe is stored and which can adjust an air supply amount; An air hose providing a path for the air supplied from the air header to move to the chute outlet pipe; And At least one is installed on the outer circumferential surface of the chute outlet pipe, characterized in that it comprises an air nozzle for connecting the air header to the chute outlet pipe to guide the air passing through the air hose to the chute outlet pipe Fly ash discharge device. The method of claim 2, And the air hose is installed at both ends thereof and includes quick couplings connecting the air hose to the air nozzle and the air header.

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