NL8602941A - Cyclone to remove dust from gas - has tangential, pref. rectangular section, inlet to cylindrical housing wall with smooth transition to conical wall - Google Patents

Abstract

The cyclone for removing dust from dust-carrying gas comprises a housing witha cylindrical and a (downwardly converging truncated) conical portion. The tangential gas inlet duct has at least one but preferably two (opposite) side walls parallel to a plane tangential to the cylindrical portion, thus duct preferably having a rectangular section. The inner surface of the inner duct side wall pref. forms an acute-angled edge with the inner surface of the portion. The two portions preferably connect via a smoothly curved transition.

Description

i%

Short note: Cyclone

The present invention relates to a cyclone comprising at least a cylindrical and a conical part for removing dust from a dust-containing gas.

Such cyclones are generally known.

Such known cyclones have the drawback that only a relatively small part of the dust contained in the supplied air is separated, so that the air leaving the cyclone is still seriously contaminated. This phenomenon mainly occurred when cleaning flue gases from a combustion boiler, where there are very fine dust particles and fly ash. Up to now, flue gases have therefore mainly been removed from dust and fly ash by the use of textile filters. However, these filters are bulky, expensive and require frequent maintenance, so that operation of such filters is expensive. Moreover, with constant supply of gases to be cleaned, these filters have an increasing passage resistance due to the accumulating substance.

The object of the present invention is therefore to provide an apparatus for removing dust from a dust-containing gas, wherein the major part of the dust content of the gas to be cleaned is removed and wherein the passage resistance is substantially constant.

This object is achieved with a cyclone, in which at least one of the side walls of the tangential inlet channel extends parallel to an interface of the cylindrical part of the cyclone.

This measure achieves a virtually laminar flow in the cyclone, so that even the smallest dust particles are brought close to the wall of the cyclone, where they are discharged by the helical gas flow.

The invention will now be explained with reference to an exemplary embodiment, which is shown in the accompanying drawings, in which: 8602941 t * - 2 -

Figure 1: a partly broken away perspective view of a cyclone according to the present invention;

Figure 2: a partly broken away sectional view of a detail of a cyclone according to the present invention;

Figure 3: a cross-sectional view of an assembly of a number of cyclones according to the present invention;

Figure 4: an exploded view of an embodiment of an assembly of cyclones according to the present invention.

Figure 5: a partly broken away perspective view of an assembly of a number of cyclones according to the present invention; and Figure 6: a partially broken away view of a detail of the cyclone assembly of the present invention.

A cyclone 1 according to the present invention, as it is shown in figure 1, comprises a housing 2, which consists of a cylindrical wall 3, and a conical wall 4 connecting smoothly thereto via a rounded part 5, connecting to the cylindrical wall 3 of cyclone 1 is provided with a supply channel 6, a side wall 7 of which extends parallel to an interface of the cylindrical wall and seamlessly merges into this cylindrical wall. The inlet channel is also provided with an inner side wall 8, which extends parallel to the outer side wall 7. According to a preferred embodiment, the bottom wall 9 and the top wall 10 of the inlet channel are formed such that the cross section of the inlet channel 6 forms a rectangle. The discharge angle, i.e. the angle between the inner side wall 8 of the inlet channel 6 and the cylindrical wall 3 of the cyclone is sharp. The above-mentioned measures aim to keep the flow within the cyclone as laminar as possible.

The conical wall 4 leads to an outflow opening 11, through which the separated dust is discharged. In order to retain the flow profile at the outflow opening as much as possible, the edge 12 of the outflow opening 11 is sharp, as shown in figure 2. The outside of the conical wall is chamfered inwardly in the vicinity of the edge 12.

An outflow pipe 14 is arranged on the top wall 13 of the cyclone, which extends into the conical part of the cyclone. The surface of the outflow opening 15 is equal to the surface of the outflow opening 11 for the dust to be discharged and of the surface 10 of the cross section of the inlet channel 7. According to a preferred embodiment shown in figure 3, the edge of the outflow opening 15 is also sharp , which has been achieved by chamfering the bottom edge of the outflow pipe 14.

Next, the operation of the cyclone of the present invention will be described. The gas to be cleaned is fed through the inlet channel 6 and is fed into the cylindrical part of the cyclone, where the gas flow performs as much laminar, all-round movement as possible, and whereby, due to the gravity a vertical component is added so that the gas moves down in a helical fashion. The dust particles present in the gas are subjected to the centripetal force, so that they move as far as possible on the outside of the rotating gas mass. As a result of the laminar flow, these dust particles are led downwards via a helical path, after which they finally leave the cyclone via the outflow opening 11. The purified gas is discharged upwards through the exhaust pipe 14.

Figure 3 shows a cross-sectional view of an assembly of 12 cyclones according to the present invention. The cyclones 1 are arranged around a central space 16, and are each connected to the central space 16 by means of their inlet channel 6. A supply pipe 17 is mounted on the central space 16. Cyclones 1 are otherwise constructed as described with regard to Figures 1 and 2.

Above the cyclones and surrounding the central space 16, a cap 18 is arranged, so that a discharge space 19 is enclosed between the cap 18 and the top walls 8602941 to 13-13 of the cyclones. An outlet piece 20 is attached to the cap 18.

On the underside of the assembly a apron plate 21 is provided, which is provided with twelve cylindrical aprons 22, each of which is arranged concentrically with respect to the cyclones, and which each surround an outflow opening 11 of the cyclones. The purpose of these aprons is to prevent the flow of material emerging from the outflow opening 11 from disturbing that of an adjacent cyclone. The apron plate 21 is fastened to the assembly of the cyclones 1 by means of a stud 23, a spring 24, two washers 25 and two nuts 26. The whole is fastened to a dust collecting vessel 27 by means of bolts 28.

The gases supplied via the supply pipe 17 enter 15 in the central space 16, where they are evenly distributed over all inlet channels 6, and thus over all cyclones, by means of the protrusion 29. The purified gases exiting through each of the outflow pipes 14 are collected in the discharge space 19 and discharged via the outlet 20. The dust emerging from the outflow openings 11 is collected in the dust collecting vessel 27.

Figure 4 shows how the components of the cyclone assembly are constructed. The cyclones are composed of four castings; the cyclone-25 casting 30, the top plate casting 31, the cap 18, and the apron plate 22. Each of these pieces is preferably cast by casting in accordance with the desired precision requirements. During mounting, the castings 18, 31, 30, 22 are joined together by means of bolts 28, 23.

The partially broken away view of the cyclone assembly shown in Figure 5 shows that the configuration of each of the cyclones corresponds to the cyclone described with reference to Figure 1.

Figure 6 shows a partly broken-away inner view of the central space 16, within which a control cylinder jacket 32 is arranged. The control cylinder jacket 32 is provided with openings 33 on its underside, which, when the control cylinder jacket is in its lowest position, leaves a number of inlet channels 6 free. The other inlet channels are then closed. This cylinder jacket 32 can be moved up and down within the central space 16 by means of an operating eye 34 extending through an opening arranged in the side wall of the central space 16. By closing off part of The cyclones make it possible to shut off part of the cyclones with a reduced supply of flue gases to be cleaned, so that the input speed of the flue gases to be cleaned in the cyclones is maintained as much as possible, so that conditions in the cyclones are kept within limited limits. vary, which of course benefits the operation of the cyclones.

In the present exemplary embodiment, the control cylinder jacket 32 shuts off half the number of cyclones. It is of course also possible to close off another part of the number of cyclones.

8602941

Claims (17)

1. At least one cylindrical and a conical part comprising a cyclone for removing dust from a dust-containing gas, characterized in that at least one of the side walls of the tangential inlet channel is parallel to an interface of the cylindrical part of the cyclone extends. Cyclone according to claim 1, characterized in that two side walls of the inlet channel extend parallel to an interface of the cylindrical part of the cyclone. Cyclone according to claim 1 or 2, characterized in that the inlet channel has a rectangular cross section. Cyclone according to any one of claims 1 to 3, characterized in that the outflow angle of the inlet channel is sharp. Cyclone according to one of the preceding claims, characterized in that the transition between the cylindrical part and the conical part is rounded. Cyclone according to one of the preceding claims, characterized in that the outlet angle of the bottom outlet opening is sharp. Cyclone according to any one of the preceding claims, characterized in that the edge of the gas discharge opening is sharp. 8. Cyclone according to any one of the preceding claims, characterized in that the area of the gas outlet opening is equal to the area of the bottom outlet opening. Cyclone according to any one of the preceding claims, characterized in that the area of the outflow channel is equal to the area of the bottom outflow opening. 10. A plurality of cyclones according to any one of the preceding claims, characterized in that the cyclones are arranged in an annular manner around a central space, and that the inlet channels are connected to the central space, and that a supply channel opens into the central space. . 8602941 - 7 - Assembly according to claim 10, characterized in that the housing surrounding the cyclones and the central space is made by casting. 12. Assembly according to claim 10 or 11, characterized in that a cylindrical apron is arranged concentrically with each cyclone on the underside of each of the cyclones. 13. An assembly according to claim 12, characterized in that each of the aprons is fixedly connected to a central plate. Assembly according to claim 12 or 13, characterized in that the central plate and the aprons consist of one casting. Assembly according to any one of claims 10-14, 15, characterized in that a shut-off valve is arranged in the central space for closing off a number of the supply channels of the cyclones. 16. Assembly as claimed in claim 15, characterized in that the valve is formed by a cylinder jacket movable in vertical direction, which is provided with openings on its underside. Assembly according to any one of the preceding claims 10-16, characterized in that the inner walls of the cyclones are enameled. 8692941