CZ31680U1 - A powder sorbent application nozzle - Google Patents

Description

The invention relates to a nozzle which is intended for the application of powdered sorbent carried by compressed air into the air stream and which is formed by a pipe projecting from the wall of the flue gas duct.

BACKGROUND OF THE INVENTION

A sorbent absorbing acidic and other undesirable components of the flue gas is sprayed into the flue gas flowing through the flue gas duct, its containment extension or the connected reactor. The sorbent is fine dust with a granulation of about 90 pni, most often lime hydrate, soda, etc. The sorbent is dosed from a storage silo controlled into a mixer in which it is mixed with compressed transport air. The sorbent / air mixture is then introduced into the flue gas stream. This is done by a spray nozzle embedded in the flue gas duct or other flue gas duct and fixed to the flue gas duct wall by a flange connection. The sorbents dispersed in the air are collected together with the pollutants by the filters installed at the end of the flue gas draft.

Known nozzles for the application of the dust material are solid tubes ending in the flue axis. They can be terminated by a perpendicular or oblique cut, or an oblique reflective surface is placed in front of their mouth. Their disadvantage is that the sorbent feeds only to a limited part of the flue gas stream, usually near the center of the flue gas cross-section; initially, the sorbent is entrained in part of the stream, and only after it has traveled a certain distance is it dispersed by the turbulence, imperfectly, throughout the profile. This limits the intensity of the desired chemical reactions; existing nozzles thus do not ensure optimum sorbent performance over the entire path from nozzles to filters.

The invention aims to substantially reduce the disadvantages of known nozzles of this type.

The essence of the technical solution

This object is solved by a nozzle which is designed to apply powdered sorbent carried by compressed air into the air stream and which is formed at the end by an open tube protruding from the flue wall. The essence of the nozzle is that it is provided with at least one longitudinal slot for permeating the sorbent.

The nozzle is preferably provided with two parallel slots located on the flood side of the tube symmetrically about a plane of symmetry passing through the nozzle axis.

The width of the slot towards the distal end of the nozzle is variable to ensure uniform sorbent dosing into the transverse profile of the flue.

In order to limit the deposition of sorbent on the walls of the flue gas duct, the distance of the proximal end of the slot from the flue gas duct wall is at least twice the pipe diameter.

The slots may be interrupted by reinforcing bridges.

The mouth of the tube may be provided with a reflective surface directing the sorbent in the air flow direction.

- 1 GB 31680 U1

Clarification of drawings

1 to 6 show a preferred embodiment of a powder sorbent nozzle, FIG. 1 in a side view, FIG. 2 in a front view, FIG. 3 in a plan view, FIG. 4 in a longitudinal view. 5 in section AA according to FIG. 4 and FIG. 6 in axonometric projection. The arrow shows, with the exception of FIG. 3, the direction of flow of the air mass around the nozzle.

Examples of technical solutions

The nozzle according to FIGS. 1 to 6 is formed by an open steel tube 1, the diameter of which is dimensioned according to the desired flow rate of the sorbent mixture and the conveying and atomizing compressed air. On both sides of the tube 1, longitudinal slots 2 are arranged symmetrically on its lava side in accordance with a plane of symmetry passing through the axis of the nozzle. The angle α between the radials passing through the tube 1 through the slots 2 is preferably 90 ° to 180 °. Through the slits 2 the sorbent flows from the pipe 7 into the flue gas. The slots 2 may change their width towards the distal end of the tube 7. The width of the slots 2 and the rate of change thereof are determined individually in order to ensure a homogeneous distribution of the sorbent in the volume of the air mass. When calculating resp. In addition to the mass and pressure conditions in the nozzle, the computer simulation should also take into account the velocity profile of the air flowing around the individual nozzles and their arrangement in the velocity field of the air in the flue gas duct.

The sorbent that has not exited the tube 1 through the slits exits from the tube 2 by its open end provided with a reflective plate 3. The proximal end of the slots 2 should be at least twice the diameter of the pipe flue. To maintain the rigidity of the tube 1, the slots 2 are interrupted by bridges 4.

To ensure perfect homogenization of the sorbent in the air, it is usually necessary to introduce several nozzles radially in the air stream in order to better cover the cross section of the flue gas duct, taking into account the air velocity profile at the installed nozzles.

PROTECTION REQUIREMENTS

Claims (5)

A nozzle, which is formed at the end by an open tube (1) projecting from the wall of the flue gas duct, and which is intended to apply a powdered sorbent carried by compressed air into a stream 5, characterized in that it is provided with at least one longitudinal slot (2) for permeating the sorbent. Nozzle according to claim 1, characterized in that it is provided with two parallel slots (2) disposed on the valley side of the nozzle (1) symmetrically with respect to the plane of symmetry o passing through the nozzle axis. Nozzle according to claim 1 or 2, characterized in that the slots (2) have a variable width. Nozzle according to one of Claims 1 to 3, characterized in that the distance of the proximal 15 of the end of the slot (2) from the flue gas duct wall is at least twice the diameter of the pipe (1). Nozzle according to one of Claims 1 to 4, characterized in that the slots (2) are interrupted by reinforcing bridges (4). Nozzle according to one of Claims 1 to 5, characterized in that the mouth of the tube (1) is provided with a reflective surface (3) pointing the sorbent in the direction of flow of the air mass.