FI76930B - CYLINDRICAL COIL WITH FILTERENHET. - Google Patents

Description

1 76930

Cyclone separator with filter unit

The invention relates to dust separators and more specifically to a cyclone separator with a filter unit, which separates the dust from the gas, the filter unit being arranged in the central tube of the cyclone separator and there is an annular gap between the filter unit and the central tube.

Cyclone separators are often used to separate impurities from gas (air). The cyclone separator includes 10 cylindrical sheaths with a tangential gas inlet and a bottomed bottom cone associated with the dust outlet. Inside the jacket is a central tube which joins the gas outlet and is located in the middle of the cyclone separator. Due to the tangential gas inlet of the cyclone separator 15, the inflowing gas begins to circulate and expel the dust particles towards the jacket surface of the cyclone separator. The circulating particles are affected by centrifugal force, gravity and the movement of the gas towards the gas outlet (center tube).

20 The separated dust circulates downwards towards the bottom of the cyclone separator, the bottom cone and the dust outlet, while the purified gas passes through the central pipe (outlet). Since the rotational motion and the air velocity toward the outlet cannot be reduced by any amount, the resolution of the cyclone separator-25 is always physically limited. The rotational movement in the center tube can be limited slightly by means of guide rails or wings in the center tube, which increases the degree of separation of the cyclone separator. The cyclone separator is sometimes combined with a filter unit to separate particles from the gas that are not separated by rotational motion in the cyclone separator.

There are several cyclone separators on the market that have attempted to use this combination to obtain a small volume of equipment. However, the hitherto known designs of such combination separators 35 have a poor degree of efficiency, since the filter unit requires a large space, which adversely affects the design of the cyclone separator.

DE-A-16 07 592 discloses a cyclone separator according to the preamble of claim 1, which is provided with a filter unit for separating dust from a gas. The filter unit is located in the center tube of the cyclone separator and there is a ring gap between the filter unit and the center tube. The filter unit may be paper or made of textile material, plastic, dense yarn fabric or the like. However, the application does not disclose that in this known cyclone separator the filter unit is corrugated longitudinally. By corrugating the filter unit, the advantage is achieved that the rotational movement and the air velocity in the central tube are made slower.

In order to provide a compact dust separator consisting of a cyclone separator and a filter unit, and at the same time to obtain maximum separation efficiency, the cyclone separator according to the invention has the characteristic features according to claim 1.

When the filter media of the filter unit is used to slow the rotation and the air velocity in the center tube, especially for small dust particles, the efficiency and separation power increase significantly in the cyclone separator, the lower amount of dust loads the filter and the flow losses are lower. The corrugated filter structure provides a larger filter surface, which reduces pressure drop losses in the entire filter unit. The corrugated channel between the center tube and the filter acts as a gas gravity device.

To further explain the invention, embodiments thereof will now be described with reference to the accompanying drawing, in which: Figure 1 shows a schematic vertical sectional view of a cyclone separator; Fig. 2 shows a cross-sectional view along the line A-A in Fig. 1; 76930 Fig. 3 shows a side view of the filter unit; Fig. 4 shows a side view of the central tube; Fig. 5 is a comparative diagram showing the degree of separation in different cyclone separator tracks; and Fig. 6 is a vertical sectional view of the center tube in a modified embodiment.

The cyclone separator includes a cylindrical jacket 10 with a tangential inlet 11 for gas (air) containing dust. At the bottom, the jacket 10 joins the bottom cone 10 12 and the dust outlet 13, which in turn joins the dust reservoir 14. Inside the jacket is a central tube 15 suspended by a rubber film 16 attached to the jacket. The central tube tapers conically towards its lower end, i.e. towards the inlet end, and has a protrusion 17 at this end.

15 Coaxially, a filter 18 is arranged in the central tube, which also tapers conically towards its lower, closed end. The filter also rests on a membrane and can be removably attached. It may consist of a paper or textile material or a metal mesh, a ceramic material or a plastic material, or also various combinations of these materials in accordance with the principles generally applied in filter technology. The filter is formed with longitudinal folds and is supported on the inside by a torn tube 19 of rigid material (paper, metal or plastic) 25 which supports the filter at the inner folds. This tube also rests on the membrane and can be formed in the same unit as the filter. An annular gap 20 is arranged between the filter and the central tube.

The contaminated gas passes through the inlet 11 of the cyclone and circulates along the jacket 10 of the cyclone. Due to the centrifugal force and gravity, the impurities 35 are pressed down into the dust storage 14 and separated here.

The purified gas, which continues to rotate, rises toward the inlet of the central tube 4 76930, where the gas is forced out over the corrugated surface of the filter 18 into the slot 20. The corrugated filter surface stabilizes the gas by braking the remaining rotational forces so that the laminar gas-5 .

Those fine dust particles that cannot be separated by the cyclone effect adhere to the filter surface. Due to the corrugated filter structure, the filter surface is relatively large and the flow losses are relatively small, so that large amounts of fine dust can be separated in the filter structure itself. When the gas flow is shut off, the fine particles detach from the corrugated filter surface and fall down to the separated dust in the dust storage 14.

Because the filter is corrugated longitudinally, a very efficient cyclone separator is obtained. Instead of conductor rails, the filter acts as a means of braking the central cyclone vortex, thereby increasing the degree of separation of the cyclone separator. This is illustrated in Figure 5, where the horizontal axis indicates particle size, jam, and the vertical axis il-20 indicates the degree of separation,%. Curve A denotes a cyclone device without a filter unit, curve B denotes a cyclone separator with a cylindrically corrugated filter unit, and thus indicates the degree of separation of the cyclone device itself (not the filter), and curve C indicates smoother than curve B tapers towards the lower end and is located in a downwardly tapering center tube, as in the embodiment shown and described. The curves are based on laboratory experiments. Because the cyclone separator has a higher degree of separation, the filter is significantly less loaded, resulting in lower flow losses.

The central tube 15, together with the filter 18, forms a compact unit which, because it is suspended on a rubber film 16, can be shaken in a simple manner to clean the surface of the filter-35. Dust particles that have adhered to the corrugated filter surface then fall out through the central tube and down through the lower part of the cyclone separator into the dust container. Because the corrugated filter is conical relative to the center tube (tapers toward the lower end), it is easier to clean the filter unit because the slope of the filter facilitates the drainage of dust.

The ideal design appears to be that of the embodiment shown and described, in which the central tube is weakly conical and also the filter unit is conical, but at a greater angle. Thus, in Figures 3 and 4, <A must be in the range of 0-30 ° and / * in the range of 0-25 °. In addition, ¢ 1>. In the experiment, which is the basis of curve C, the angles were d = 8 ° and / 3 = 5 °.

In the embodiment according to Fig. 6, a plurality of filters 18 having the previously described structures are arranged in a central tube 15, which in this case extends below the lower ends of the filters, the central tube in the part extending below the filters being internally provided with vanes or guide rails 24.

Claims (8)

A cyclone separator with a filter unit (18) for separating dust from a gas, the filter unit 5 being arranged in the central tube (15) of the cyclone separator and the ring gap (20) being arranged between the filter unit and the central tube, characterized in that the filter unit (18) is corrugated longitudinally. Cyclone separator according to Claim 1, characterized in that the filter unit (18) is conical and tapers towards the inlet end of the central tube (15). Cyclone separator according to Claim 1 or 2, characterized in that the surrounding central tube (15) is conical and tapers towards its inlet end. Cyclone separator according to one of Claims 1 to 3, characterized in that the surrounding central tube (15) has a projection (17) at its inlet end. Cyclone separator according to Claim 2 or 3, characterized in that the filter units (18) are arranged in parallel in the central tube (15). Cyclone separator according to one of Claims 1 to 5, characterized in that the central tube (15) 25 is provided internally with vanes or guide rails (24). 6 76930 Cyclone separator according to one of Claims 1 to 6, characterized in that the filter unit (18) and the surrounding central tube (15) are suspended by means of a flexible membrane (16). Cyclone separator according to one of Claims 1 to 7, characterized in that the filter unit (18) is internally supported by a torn support tube (19) for internal filter folds.