WO2020187653A1 - Filter assembly of the cyclone separator type with turbulence body - Google Patents

Abstract

The invention relates to a filter assembly of the cyclone separator or cyclone filter type, having a filter housing that is rotationally symmetrical about a longitudinal axis and that radially surrounds a filter element, which is arranged centrally in relation to the longitudinal axis, is hollow-cylindrical, and surrounds an inner, cylindrical filter space, and that together with the filter element delimits a flow channel of annular cross-section, which flow channel has a swirling space, into which a flow feed leads eccentrically and transversely to the longitudinal axis, and also a separation channel, which, along the longitudinal axis, adjoins indirectly or directly downstream of the swirling space. The invention is characterised in that a number of rod-like turbulence bodies are provided in a circular arrangement around the filter element and are in the form of rods or pins having a round, oval or N-sided cross-section, with the longitudinal extent of said turbulence bodies being oriented parallel to the longitudinal axis of the straight hollow-cylindrical filter element.

Description

Filter arrangement like a centrifugal separator with a turbulence body

Technical area

The invention relates to a filter arrangement of the type

Centrifugal separator or cyclone filter with a around a longitudinal axis

rotationally symmetrical filter housing that is centric to the longitudinal axis

arranged, hollow cylinder-shaped and enclosing an inner, cylindrical filtrate chamber radially and with this delimits a flow channel with an annular cross-section, which has a swirl chamber into which a flow inlet opens off-center and transversely to the longitudinal axis, as well as a central or immediately downstream along the longitudinal axis to the swirl space

having subsequent separation channel.

State of the art

Generic filter arrangements, which are designed in the manner of a centrifugal separator and are often also referred to as cyclone filters, use the separating effect of centrifugal force, which acts on particles of solid substances contained within a gaseous or liquid swirl flow. A rotationally symmetrically designed filter housing, which is essentially tubular and laterally eccentric, serves to generate the swirl flow

Longitudinal axis provides a flow inlet through which the medium to be filtered is fed in with the formation of a swirl flow oriented around the longitudinal axis. In the center of the longitudinal axis, a tubular filter element is attached within the filter housing, which is subjected to a vacuum

Flow diversion is fluidically connected. The centrifugal force driven

Segregation of contained within the gaseous or liquid medium Particles of solid substances lead to an accumulation of the particles in the area of the filter housing wall, which radially surrounds the filter element, along which the particles are collected by flow dynamics and, if necessary, disposed of. On the other hand, the flow areas of the swirl flow, which the filter wall of the central

arranged tubular filter element flow directly around, largely purified and contain at most light-weight particles of solid substances, which must be prevented from passing through the filter wall into the interior of the filter element. For this purpose, the filter grain size of the filter wall is selected in a suitable manner, so that on the one hand a desired filter effect and on the other hand a sufficient flow passage through the filter wall into the interior of the filter element to produce a cleaned, i.e. filtered mass flow can be achieved.

The document EP 2 049 222 B1 discloses a generic filter device for separating impurities from a fluid stream by using a filter element which is accommodated in a filter housing, the

The filter housing has a swirl chamber in such a way that the fluid flow to be filtered is at least partially guided around the filter element in a swirl flow.

An inlet through which the medium to be filtered is fed opens into the swirl chamber, which is designed in the form of a conical widening of the filter housing, eccentrically to the longitudinal axis. The filter element extending along the filter housing tapers conically with increasing distance from the swirl chamber and is connected in a fluid-tight manner in the area of the swirl chamber to an outlet for the filtered medium from the interior of the filter element.

The mode of operation of known centrifugal separators sees one

pressurized, opening into the swirl chamber of the filter housing

filtering fluid flow, which helically flows over the elongated tubular filter element with the formation of a swirl flow and, when pressurized, passes radially from the outside through the filter wall into the interior of the filter element, removing particles of solid substances. The cleaned filtrate flow is pressure-driven from the inside of the filter element via the drain to the outside. System-related, adhering in and on the wall of the filter element

Filter residues lead to a deterioration in the filter effect and make

Filter cleaning measures often required. For example, backwashing the filter arrangement with cleaning air is suitable for this purpose.

The document DE 198 44 441 A1 describes a device for separating particles from a fluid with a rotating filter.

The document DE 198 11 090 A1 discloses a cyclone separator with a rotationally symmetrical housing, an inlet for a fluid containing dispersed substances and in each case at least one outlet for the dispersed substances and for the cleaned fluid. The inlet opens into an annular channel. A part of the housing wall is formed in the fleas of the annular channel in the form of a flow straightener connecting the annular channel to the interior of the housing. The inside of the housing is in the form of a front end

Shell-shaped bottom wall is formed, the bottom wall being penetrated by a pipe arranged concentrically to the longitudinal axis, which protrudes from the bottom wall in the direction of one end face and serves as an outlet for the cleaned fluid. In the bottom wall are near the pipe

Drainage openings are provided which serve as an outlet for the dispersed substances.

Presentation of the invention

The invention is based on the object of a filter arrangement in the manner of a centrifugal separator or cyclone filter with a filter around a longitudinal axis

rotationally symmetrical filter housing that is centric to the longitudinal axis

arranged, hollow cylinder-shaped and enclosing an inner, cylindrical filtrate chamber radially and with this delimits a flow channel with an annular cross-section, which has a swirl chamber into which a flow inlet opens off-center and transversely to the longitudinal axis, as well as a central or immediately downstream along the longitudinal axis to the swirl space,

subsequent separation channel has to be developed in such a way that the the above measures for filter cleaning are no longer required or at least in significantly larger amounts compared to previously known solutions

Are to be carried out at intervals.

The solution to the problem on which the invention is based is specified in claim 1. Developing the idea of the invention in an advantageous manner

Features are the subject matter of the subclaims and the further description with reference to the exemplary embodiments.

A filter arrangement according to the solution with the features of the preamble of claim 1 is characterized in that a number of rod-like turbulence bodies are provided in a circular arrangement around the filter element, which are in the form of round, oval or N-shaped rods or pins in cross section and their longitudinal extensions are each oriented parallel to the longitudinal axis of the straight hollow cylinder-shaped filter element.

The helical flow of the fluid to be filtered that forms within the separation channel flows around the radially outer jacket surface or the outer one

Filter wall of the hollow cylindrical filter element with

Flow proportions caused by the prevailing in the helical flow

Centrifugal force are largely purified. Nonetheless, these flow components flowing around the filter element close to the wall also contain solid components which can at least temporarily stick to the openings in the perforated filter wall. By providing the transverse or oblique to

Direction of flow around the helical flow oriented, rod-like or rod-like turbulence bodies, which directly or indirectly on the lateral surface of the

Hollow-cylindrical filter element are attached, eddies form downstream of the overflow and / or flow around each of the turbulence bodies, in the form of so-called Lee vortices, through which material settling

Contamination on the filter wall is avoided or at least made significantly more difficult. The Lee vortices represent local flow rotors, with a

Rotor vortex orientation that is opposite to the overflow and / or flow around the direction is directed. As a result, the filter wall is acted upon in these flow regions with fluid flow components which are oriented largely orthogonally towards and away from the filter wall. In addition to the already mentioned effect of making material particles more difficult to settle in the filter wall openings or on the filter wall surface, this is also continuously cleaned.

The turbulence bodies are preferably each arranged with an equidistant circular spacing around the filter element and each extend along the entire length of the filter element.

The turbulence bodies can either be attached seamlessly directly to the outer surface of the straight, hollow cylinder-shaped filter element or attached to the outer surface of the straight, hollow-cylindrical filter element with a spacing or different spacing.

In the first case, a previously explained flow pattern with a Lee vortex is established. In the second case, depending on the selected distance with which each of the rod-shaped or rod-shaped turbulence bodies is arranged at a distance from the radially outer filter wall, in addition to the Lee vortex formation explained, a fluid flow close to the wall is established, which through the

Filter wall and each of the turbulence bodies locally enclosed gap

passes through. The gap that is locally enclosed by the turbulence bodies with the filter wall preferably has a gap or spacing that corresponds to at least half of a largest diameter that can be assigned to the cross section of the turbulence body and at most three times the largest diameter.

Depending on the choice of the distance dimension and the cross-sectional shape of the turbulence bodies, the Bernoulli effect comes into play when the air flows through the gap, which results in an increase in flow velocity with a simultaneous local Adjust pressure drop. The Bernoulli effect thus helps to clean and keep the filter wall openings clean.

The hollow cylindrical filter element preferably has a perforated sheet metal or a composite of at least two lattice structure or wire mesh layers, each with lattice openings, the lattice openings of which differ at least in opening size. In the case of the use of lattice structure or wire mesh layers, that layer with the smaller lattice openings is arranged radially on the outside. In addition, the at least one lattice structure or wire mesh layer arranged radially on the outside has elongated lattice or wire segments, the longitudinal extent of which is oriented parallel to the longitudinal axis.

The arrangement according to the solution of the rod-shaped or rod-shaped

Turbulence bodies on and around the hollow cylindrical filter element in the form of an arrangement fixed in space to the filter element can advantageously be used in cyclone filters which are operated in different ways.

For example, a preferred embodiment provides for the integration of the turbulence bodies in accordance with the solution in a filter arrangement, in which a region of the flow channel axially opposite the swirl space to the longitudinal axis

The flow outflow emerges eccentrically and transversely to the longitudinal axis from the separation channel, which is fluidically connected to a first suction unit that generates a flow suction. The flow inlet is pressurized with a fluid to be filtered, with a helical flow forming within the flow channel and oriented around the longitudinal axis with a flow direction specified by the swirl chamber and one exclusively through the first

Suction unit certain flow velocity is generated which the

Turbulence body flows over transversely or obliquely to their longitudinal extensions. For the purpose of discharging the filtrate that has passed through the filter wall into the filtrate space and is thereby cleaned, the filtrate space has a filtrate outlet in which a second suction unit is arranged, which generates a flow suction. An alternative filter arrangement provides a pressure source along the flow inlet through which a pressurized fluid to be filtered reaches the swirl space, with a helical flow forming within the flow channel and oriented around the longitudinal axis with a predetermined through the swirl space

Direction of flow and one determined by the pressure source

Flow velocity is generated, which flows over the turbulence bodies transversely or obliquely to their longitudinal extensions. In this case too, the filtrate space is fluidically connected to a filtrate drain, in which, however, no suction unit is required.

A filter arrangement designed according to the solution is particularly suitable for the filtration of fluids in the form of aerosols or suspensions, in which a fluid to be filtered is provided to the filter arrangement through the flow inlet in a pressureless or pressure-driven manner.

A preferred embodiment of the filter arrangement designed according to the solution is illustrated below with reference to figures.

Brief description of the invention

The invention is hereinafter described without limiting the general

The concept of the invention described by way of example with the aid of exemplary embodiments with reference to the drawings. Show it:

Fig. 1 a longitudinal section through a vacuum-operated filter arrangement,

Fig. 1b is a longitudinal section through an overpressure-operated filter arrangement,

2a cross-sectional representation of a filter element with directly on the

Filter outer wall attached turbulence bodies as well

Fig. 2b cross-sectional view of a filter element spaced apart from

Filter outer wall attached turbulence bodies. Ways to carry out the invention, commercial utility

The filter arrangement 1 has a filter housing 2, which is preferably designed in one piece, and an upper swirl chamber 3 as well as a preferably conically tapering, immediately adjoining downward

Separation channel 4 includes. However, the separation channel can also

be designed in the shape of a straight cylinder or a straight ring cylinder. The

The filter housing 2 is essentially rotationally symmetrical about the longitudinal axis 5 and, in the area of the swirl space 3, has a flow inlet 6 which opens into the swirl space 3 essentially transversely to the longitudinal axis 5 and eccentrically to the longitudinal axis 5. A gaseous or liquid fluid F to be filtered flows in through the flow inlet 6.

The filter housing 2 comprising the swirl chamber 3 is in this area

preferably designed cylindrical. The swirl space 3 is sealed fluid-tight on one side upward to the longitudinal axis 5 and opens along the longitudinal axis 5 directly into the conically shaped separation channel 4

A cylindrical filter element 7 extends through the longitudinal axis 5 through the swirl space 3 and the separation channel 4. In this way, an effective swirl flow D with a high swirl number can develop within the swirl space 3 before the swirl flow D passes into the separation channel 4 with the formation of a helical flow H.

Depending on the design and mode of operation of the filter arrangement, the

Flow initiation for the formation of the swirl and helical flow take place over- or underpressure-driven.

In the case shown in FIG. 1 a, a suction unit 9, preferably in the form of a suction pump, is integrated along a flow drain 8 fluidically connected to the separation channel 4 in order to generate a swirl and helical flow that forms within the filter housing 2. By means of the suction unit 9, the fluid F to be filtered is fed into the interior of the Filter housing 1 sucked, whereby the entering the swirl chamber 3, to be filtered fluid F through the predetermined cylindrical contour in a

Swirl flow D is forced in the area of the swirl space 3 and the

Longitudinal axis 5 and the tubular filter element 7 arranged centrically to the longitudinal axis 5 rotates. Due to the suction effect of the suction unit 9, the swirl flow D formed in the form of a vortex of rotation within the swirl space 3 changes into a helical flow H flowing helically around the tubular filter element before it exits the filter housing 2 via the flow outlet 8.

The straight hollow cylinder-shaped filter element 7 has, at its end region facing away from the swirl chamber 3, a filtrate drain 10, along which a second suction unit 11 is arranged. Depending on the nature of the fluid F to be filtered and the type and size of the particles of solid substances contained in the fluid F to be filtered, the filter effect can be individually adapted by means of the second suction unit 11. In addition, the throughput of the fluid F to be filtered, which passes through the entire filter arrangement along the swirl chamber 3 and the separation channel 4, can be preset by means of the first suction unit 9.

As an alternative to the vacuum-driven design and mode of operation of a cyclone filter arrangement according to FIG. 1a explained above, the fluid can be fed under pressure instead of a pressureless fluid feed. For this purpose, a fluid feed pump 12 is arranged in the flow inlet 6, which, driven by pressure, feeds the fluid F into the swirl space 3 and the adjoining separation channel 4, forming the swirl and helical flow D, H, see FIG. 1 b. The straight hollow cylinder-shaped filter element 7 is fluidically connected to a filtrate drain 10, via which the cleaned filtrate emerges from the filter arrangement.

The filter element 7, which is preferably designed in the shape of a straight hollow cylinder, has a filter wall which preferably consists of a perforated, largely mechanically wear-resistant sheet metal. Alternatively, it is possible to form the filter wall from a composite of at least two grids or wire mesh layers, which each have lattice openings whose lattice openings differ from one another in terms of position in such a way that the lattice structure or

Wire mesh layer is arranged with the respective smaller grid openings radially outside to the straight hollow cylinder-shaped filter element. In addition, it is advantageous to arrange the lattice structure or wire mesh layer, which is arranged at least radially on the outside and preferably has elongated lattice or wire segments, in such a way that the longitudinal extension of the lattice or

Wire segments is oriented as parallel as possible to the longitudinal axis 5 of the filter arrangement. In this way, each individual grid opening is formed close to the surface

Flow turbulences that prevent or make it more difficult for particles of solid substances to settle inside and on the filter wall.

In order to significantly support the formation of the flow turbulence and to prevent particles of solid substances from settling inside, but above all on or on the filter wall, the filter arrangement 1 is characterized in that in a circular, preferably uniformly distributed arrangement around the straight cylinder-shaped filter element 7, a number of rod-like formed turbulence body 13, for example in the form of rods or pins with a round, oval or N-cornered cross section, see FIG. 2a, is attached, the longitudinal extensions of which are each oriented parallel to the longitudinal axis 5 of the straight hollow cylinder-shaped filter element 7. The rod-like turbulence body 13 can directly, s. 2a, or be arranged at a distance from the filter wall surface of the filter element, see FIG. Figure 2b. The rod-like turbulence bodies 13 are overflowed by the helical flow H obliquely or orthogonally to their longitudinal extension, whereby in each case in

Direction of overflow immediately after each turbulence body 13

Form flow vortices, so-called Lee vortices 14, which prevent or at least make it more difficult for particles to settle in and on the filter wall openings.

The direct attachment of the rod-shaped or rod-shaped turbulence body 13 to the outer wall of the hollow cylindrical filter element 7, see

Cross-sectional representation in FIG. 2a takes place with known joining techniques. There the turbulence bodies 13 are made of abrasion-resistant material, preferably metal, solder, weld or adhesive connections are suitable.

In the case of the radially spaced apart from the filter outer wall of the

Turbulence bodies 13 need to be attached directly or indirectly to the top and bottom of the filter, for example using a fastening ring or ring that is firmly attached to the filter element. The distance a between the turbulence body 13 and the outer wall of the filter is preferably at least half the largest turbulence body diameter and at most three times the largest turbulence body diameter in each case.

Due to the spacing between the turbulence bodies 13 and the outer wall of the filter element 7, fluid flows 15 close to the wall form, which due to the local flow channel narrowing due to the Bernoulli effect

Experience an increase in the flow rate and a reduction in pressure, whereby the effect on the filter wall caused by the Lee vortex formation

Cleaning effect is supported again.

List of reference symbols

1 filter arrangement

Filter housing

Swirl space

Separation channel

Longitudinal axis

Flow inlet

Filter element

Flow sequence

9 suction unit

10 Filtrate drain

11 Second suction unit

12 fluid pump

13 turbulence bodies

14 lee vortices

15 fluid flows close to the wall

D swirl flow

F fluid flow, fluid

H helical flow

Claims

Claims

1. Filter arrangement in the manner of a centrifugal separator or cyclone filter with a filter housing (2) which is rotationally symmetrical about a longitudinal axis (5) and which radially comprises a filter element (7) arranged centrically to the longitudinal axis (5) and designed in the shape of a hollow cylinder and enclosing an inner, cylindrical filtrate space with this one delimits a flow channel with an annular cross-section, which has a swirl space (3) into which a flow inlet (6) opens off-center and transversely to the longitudinal axis (5), as well as a flow duct (6) extending along the longitudinal axis (5) centrally or immediately downstream of the swirl space (3 ), adjoining separation channel (4),

characterized in that around the filter element (7) a number of rod-like turbulence bodies (13) are provided in a circular arrangement, which are in the form of rods or pins with round, oval or N-cornered cross-sections and whose longitudinal extensions are each parallel to the longitudinal axis (5) of the straight hollow cylindrical filter element (7) are oriented.

2. Filter arrangement according to claim 1,

characterized in that the turbulence body (13) each with a

are arranged equidistant circular distance around the filter element (7).

3. Filter arrangement according to claim 1 or 2,

characterized in that the turbulence body (13) directly on the

Jacket outer surface of the straight hollow cylinder-shaped filter element (7) are attached seamlessly.

4. Filter arrangement according to claim 1 or 2,

characterized in that the turbulence bodies (13) are attached to the outer jacket surface of the straight hollow cylinder-shaped filter element (7) with a distance dimension (a) or with different distance dimensions.

5. Filter arrangement according to claim 4,

characterized in that the at least one distance dimension (a) corresponds to at least half of a largest diameter which can be assigned to the cross section of the turbulence body (13) and at most three times the largest diameter.

6. Filter arrangement according to one of claims 1 to 5,

characterized in that the filter element (7) has a filter wall which has a perforated sheet metal or a composite of at least two lattice structure or wire mesh layers, each with lattice openings whose lattice openings differ at least in opening size, and

that the lattice structure or wire mesh layer with the smaller

Grid openings is arranged radially outward.

7. Filter arrangement according to claim 6,

characterized in that at least the lattice structure or wire mesh layer arranged radially on the outside has elongated lattice or wire segments, the longitudinal extent of which is oriented parallel to the longitudinal axis.

8. Filter arrangement according to one of claims 1 to 7,

characterized in that in an area of the flow channel opposite the swirl chamber (3) axially to the longitudinal axis (5), a flow outlet exits the separation channel (4) eccentrically and transversely to the longitudinal axis (5), which is connected to a first suction unit ( 9) is fluidically connected,

that the flow inlet (6) is pressurized with a fluid to be filtered, and that a helical flow (H) that forms within the flow channel and is oriented around the longitudinal axis (5) with a flow direction specified by the swirl chamber (3) and one exclusively through the first

Suction unit (9) certain flow speed can be generated which the

Turbulence body (13) flows over transversely or obliquely to their longitudinal extensions, and that the filtrate space is fluidically connected to a second suction unit (11) which generates a flow suction.

9. Filter arrangement according to claim 8,

characterized in that the filter element (7) is connected at its end region facing away from the swirl chamber (3) to a filtrate drain (10) which is fluidically connected to the second suction unit (11).

10. Filter arrangement according to one of claims 1 to 7,

characterized in that a pressure source is arranged along the flow inlet, through which a fluid to be filtered is pressurized into the

Swirl space (3) ensures that a helical flow (H) which forms within the flow channel and is oriented around the longitudinal axis (5) can be generated with a flow direction specified by the swirl space (3) and a flow speed determined by the pressure source, which the turbulence bodies (13 ) flows across or at an angle to their longitudinal extensions, and

that the filtrate space is fluidically connected to a filtrate drain (10).

11. Filter arrangement according to one of claims 1 to 10,

characterized in that the flow channel of the separation channel (4) tapers or tapers in the flow direction in the flow cross section

Geradringzyl is designed inder-shaped.

12. Use of the filter arrangement according to one of claims 1 to 11 for the filtration of fluids in the form of aerosols or suspensions, in which a fluid to be filtered is provided to the filter arrangement without pressure through the flow inlet (6).