CH673591A5 - - Google Patents

Description

DESCRIPTION

The invention relates to a filter apparatus according to the preamble of claim 1.

A filter apparatus of this type is known from US Pat. No. 2,474,478. In this known filter apparatus, the exhaust air from a textile machine room is passed through a sieve, on the inflow side of which fibers and dust settle.

The sieve forms the jacket of a continuously rotating cylindrical drum, the interior of which is connected to the suction side of a blower. The stationary blowing nozzle directed against the outflow side of the screen is connected to the pressure side of the blower. The mouthpiece, which is also stationary and opposite the blowing nozzle, is part of a collecting box, to which a line for carrying away the impurities blown off the sieve is connected.

The aforementioned known filter apparatus works satisfactorily in that only a small pressure loss has to be accepted when the air passes through the sieve and, on the other hand, the self-cleaning device effectively removes the fibers from the sieve; If the compressed air that emerges from the blower nozzle detaches the fibers from the surface of the sieve, these fibers get into the collecting box and cannot be deposited again on the sieve if they are discharged via the line connected to the collecting box. With regard to the purification of the air, however, the known filter apparatus has only limited effectiveness, in particular if dust is only retained to a small extent on the sieve. If higher demands are placed on the degree of purity of the cleaned air, the known filter apparatus is out of the question.

To achieve such a higher degree of purity, it would be necessary to use an appropriate filter medium instead of the sieve, with the consequence that, at the same speed and the same arrangement, a considerably greater pressure loss would occur than with a corresponding inadmissible increase in the energy required to transport the air would be connected. Alternatively, a low pressure loss would have to be bought with the use of such a filter medium, with a considerable increase in the filter area and thus with a considerable increase in the space requirement of the filter apparatus, which would also increase the expenditure on equipment.

The object of the invention is therefore to increase the filter area in relation to the space requirement of the same to a substantial extent in a filter apparatus of the type specified, without increasing the effort for the self-cleaning device or restricting its effectiveness.

The object of the invention is achieved by the features of the characterizing part of claim 1.

The pleating of the filter medium, in particular a zigzag pleating, can obviously achieve a massive increase in the filter area for a given dimension of the filter. It is surprising, however, that although the folds of the filter medium in the direction of flow of the air from the blow nozzle are only weakly set surfaces, a comparatively very good cleaning of the filter medium can be achieved. While a final explanation for this cleaning effect is not yet available, it can be assumed that it is related to the change in the pressure load on the folds with which the blowing nozzle extends approximately in parallel during the relative movement between the filter medium and the blowing nozzle.

The gas filter of the filter apparatus according to the invention can be constructed in a simple manner in that a plurality of plate elements form an approximately coherent filter surface, the plate elements being flat and the filter medium running in a zigzag shape therein. Such plate elements are known and are used, for example, in clean room technology for the construction of filter ceilings in rooms.

A configuration of the gas filter which is advantageous in terms of the space requirement is that the filter surface forms the jacket of a hollow body which in cross section represents a regular polygon, the longitudinal axis of the hollow body running at right angles to the cross section. In this case, the hollow body, which can be designed as a prism, is preferably mounted so as to be rotatable about its longitudinal axis, the blowing nozzle and suction nozzle being arranged in a stationary manner. It has been shown that if the number of corners of the prism is chosen to be greater than about ten, the change in distance between the filter plates and the blowing nozzle on the one hand and the mouthpiece on the other hand, which occurs when the prism rotates, is negligible for the cleaning effect.

An example of an embodiment of the filter apparatus according to the invention for cleaning the intake air of a gas turbine system is explained in more detail below with reference to the drawing. Show it:

Figure 1 is a perspective view of the filter apparatus.

Fig. 2 shows a cross section through the filter drum, and

FIG. 3 shows a detail from FIG. 2 on an enlarged scale.

1 in the drawing denotes a filter apparatus which is connected to an inlet housing 2 of a gas turbine system (not shown). The filter apparatus comprises an elongated box 3 which is square in cross section and which has at least on one of its long sides 4 a not shown, for. B. has a grille-covered intake for ambient air.

Inside the box 3, an elongated filter drum - generally designated 5 - is arranged, the longitudinal axis of which

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673 591

Longitudinal axis of the box 4 runs approximately coincident. The filter drum 5, which is open towards the inlet housing 2, has two races 6 and 7 which run on its circumference and are spaced apart from one another in the longitudinal direction and with which it is supported on pairs of rotatable rollers 8. The rollers 8, which are mounted on the box 4 in a manner not shown, form rotary bearings of the filter drum 5, on the airtight end wall 9 of which a schematically illustrated rotary drive 10 acts. The rotary drive 10, which in turn is fastened to the end wall 11 of the box 4, can comprise, for example, an electric motor provided with a reduction gear, wherein a pinion provided on the output shaft of the transmission can mesh with a toothed ring provided on the end wall 9 of the filter drum 5.

In the interior of the filter drum 5 runs parallel to its longitudinal axis and adjacent to the inside of the circumferential casing 12 there is a blast nozzle 13 (FIG. 2) which opens out from a tube 14 directed radially against the circumferential casing 12. The blowing nozzle 13 extends together with the tube 14 over the full length of the peripheral jacket 12 and is connected via the tube 14 at its end remote from the end wall 9 to a compressed air source 15.

Adjacent to the outside of the circumferential casing 12 and parallel to the longitudinal axis of the filter drum 5, an elongated suction mouthpiece 16, which is arranged opposite it and extends openly against the circumferential casing, extends over the full length of the blowing nozzle 13. The suction mouthpiece opens into a suction pipe 17, which is connected to a vacuum source 18 at its end facing the end wall 11. Via its opening 19, the vacuum source 18 is connected to a separator collector for impurities, not shown, which is arranged outside the box 3.

At its end facing the inlet housing 2, the box 3 has a partition 20 which has a circular opening (not shown) corresponding approximately to the inside diameter of the race 6. The opening is arranged concentrically to the open end of the filter drum, a seal sealing the running clearance gap being provided between the race 6 and the partition 20.

As can be seen more clearly from FIGS. 2 and 3, the peripheral jacket 12 of the filter drum 5 according to the invention forms a prism which has twelve corners in the exemplary embodiment shown. The sides of the prism are formed by longitudinal rows of rectangular flat plate elements 21, the plate elements of the rows being airtightly connected to one another in a manner not shown. On their long sides, the plate elements 21 are supported by longitudinal webs 22 which run parallel to the longitudinal axis of the filter drum and at the same time connect the races 6 and 7 and the end wall 9 to one another. The plate elements 21 along their long sides with the longitudinal webs 22 and the corresponding plate elements along the broad sides with the races or the end wall 9 are airtight. Each plate member 21 is made of a zigzag folded dust filter medium, e.g. B. made of glass fiber cellulose, and the same airtight frame. Such elements, also known as plate filters, are known and are of the same type and quality as the filter medium, for example in clean room technology, e.g. B. in filter ceilings of clean rooms. The folds 23 of the filter medium run in the longitudinal direction of the plate elements and thus parallel to the longitudinal axis of the filter drum; thus the folds also extend parallel to the blowing nozzle 13.

5 The blowing nozzle 13, the tube 14 and the compressed air source 15 and the suction mouthpiece 17 with the parts 17 and 18 belong together to the self-cleaning device of the filter apparatus, which also includes the drive 10 and a control circuit, not shown, for the same, to the filter drum 5 either periodically or io depending on the pressure drop inside the filter drum for one revolution and then stop again. The control circuit also acts on the compressed air source 15 and the vacuum source 18 in order to operate them for the duration of the rotation of the drum. The blowing nozzle 13 and the 15 mouthpiece 16 are supported on the box 3 via the parts 14 and 17 in a manner not shown.

During operation of the gas turbine system, fresh air is sucked in, which, after entering the box 3, is distributed around the circumference of the filter drum 5 through the filter medium of the plate elements 21 and passes into the inlet housing 2 from inside the filter drum. When the air passes through the filter medium, contaminants such as e.g. B. sand and dust retained with deposits on the outside. If, for example, the pressure drop has reached a certain level due to increasing occupation of the filter medium with impurities during continued operation, the self-cleaning device is put into operation via the control circuit.

When the filter drum rotates, the folds 23 of the filter medium pass under the blowing nozzle 13, the fold parts 30 being acted upon successively along their entire length by the compressed air flow (opposite to the fresh air flow). The contaminants attached to the outside of the filter medium are released from its surface so that they can be entrained and removed 35 by the air entering the suction mouthpiece.

The effectiveness of the self-cleaning device is very high, which can already be seen from the long service life of the plate elements. Of course, relatively high blowing speeds from the nozzle, preferably greater than 80 m / sec and a slow relative movement to the filter medium, for. B. cm / sec, necessary to achieve sufficient cleaning.

As the above explanations show, the effort that the self-cleaning device entails is small compared to the size of the effective filter area; this filter area can

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in comparison to the filter of a cylindrical peripheral surface of the same dimensions easily exceed twenty to thirty times.

The plate elements could of course also have a Krüm-J0 mung whose radius corresponds to the radius of a particular filter drum. On the other hand, it would also be conceivable to assemble the plate elements to form a filter wall or ceiling and to arrange the blowing nozzle and the suction mouthpiece to be movable along the same.

The filter apparatus according to the invention can obviously also be used for cleaning a gas other than air.

1 sheet of drawings

Claims (6)

673 591 7 PATENT CLAIMS 1. Equipped with a self-cleaning filter apparatus for a gas stream, with a gas filter arranged in the gas stream, which is followed by an oppositely directed, slit-shaped blowing nozzle with respect to the direction of flow of the gas stream and a mouthpiece facing the gas nozzle, which is arranged upstream, mouthpiece and Blower nozzle can be moved transversely relative to the gas filter and drive means for generating the relative movement are provided, characterized in that the gas filter comprises at least one plate element with a folded fine dust filter medium and that the blowing nozzle extends approximately parallel to the folds of the filter medium and the direction of the relative movement runs transversely to the folds, the mouthpiece being connected to a vacuum source. - 2. Filter apparatus according to claim 1, characterized in that a plurality of plate elements form an approximately coherent filter surface, the plate elements being flat and the filter medium running in a zigzag shape in them. 3. Filter apparatus according to claim 2, characterized in that the filter surface forms the peripheral jacket of a filter drum, which represents a regular polygon in cross section, the longitudinal axis of the peripheral jacket being perpendicular to the cross section. 4. Filter apparatus according to claim 3, characterized in that the peripheral jacket is part of a prism, the filter drum being rotatably mounted about its longitudinal axis, the blowing nozzle and suction mouthpiece being arranged in a stationary manner. 5. Filter apparatus according to claim 3 or 4, characterized in that the direction of flow of the gas stream through the peripheral jacket of the filter drum extends from the outside inwards. 6. Feeding apparatus according to one of claims 2, 3 or 4, characterized in that a control circuit is provided to cause the drive means to rotate the filter drum by at least a part of its circumference, and further means to supply compressed gas during the rotary movement of the blowing nozzle and to bring the vacuum source to work on the suction nozzle.