DE102018009430B4 - Filter device for separating liquid aerosols from a gas flow - Google Patents

Abstract

Filter device for separating liquid aerosols from a gas stream with
a sack-like filter pocket (4) which has an outlet opening (7) and which has a filter wall (6) permeable to the fluid flow with a pocket inside (32) and a pocket outside (30),
a frame (24) which is gas-tightly connected to a peripheral edge of the outlet opening (7),
an inlet chamber (8) which encloses the filter pocket (4) and adjoins the frame (24) in a gas-tight manner and
an outlet chamber (10) adjoining the frame (24) and the outlet opening (7) in a gas-tight manner,
wherein the pocket outside (30) forms an entry surface and the exit opening (7) forms an exit surface for the gas flow into and out of the filter pocket (4), wherein
the filter wall (6) of the filter bag (4) has a first density on the outside of the bag (30) and a second density on the inside of the bag (32) which is greater than the first density.

Description

The invention relates to a filter device for separating liquid aerosols from a gas stream.

Various filter devices for filtering aerosols from gas streams are known from the prior art, for example according to FIG DE 10 2011 122158 A1 .

the end DE 10 2012 105 936 A1 Furthermore, a filter device is known which has filter pockets for filtering out solids, which are composed to form a filter package.

DE 20 2008 006 834 U1 shows a filter element with a reinforced frame.

DE 32 22 827 A1 discloses a method for filtering raw gases with a packed moving bed.

The disadvantage of these filter devices is that they are relatively susceptible to maintenance. In particular, the aerosols filtered out often clog the filters because they cannot be transported away from the filters / membranes quickly enough or not at all. Accordingly, the filter systems show significant losses in efficiency after a short period of use.

The object of the present invention is to overcome the disadvantages of the prior art described above.

To this end, the invention proposes a filter device for separating liquid aerosols from a gas flow with a sack-like filter pocket having an outlet opening, which has a filter wall permeable to the fluid flow with an inside and a pocket outside, a frame which is gas-tightly connected to a peripheral edge of the outlet opening, an inlet chamber enclosing the filter pocket and adjoining the frame in a gastight manner and an outlet chamber adjoining the frame and the outlet opening in a gastight manner, the outer sides of the pocket forming an inlet surface and the outlet opening an outlet surface for the gas flow into and out of the filter pocket, the filter wall having a first density on the outside of the bag and a second density on the inside of the bag, which is greater than the first density.

With the device according to the invention, a gas flow, preferably an air flow, can be freed from liquid or droplet-shaped aerosols efficiently, inexpensively, thoroughly and with little maintenance. A preferred field of application of a filter device according to the invention are systems and machines in the processing industry, in particular for machining. Accordingly, the filter device is preferably used to filter suspended liquids such as cutting or lubricating oils and / or cooling liquids from the air. For this purpose, the air can be sucked out of the surroundings of the machine or an enclosed machine room, where the aerosol load is particularly high, and thus reaches the inlet chamber of the filter device. The gas flow can be sucked through the filter wall of the filter pocket, for this purpose the outlet chamber can have a negative pressure compared to the inlet chamber. Correspondingly, one filter wall or several filter walls can completely separate the inlet chamber from the outlet chamber. When passing through the filter wall, the aerosols suspended in the gas flow can wet the filter wall, so that fine aerosols agglomerate to form larger and larger liquid droplets, run down the filter pocket and drip off at a drip edge.

The filter wall can comprise layered plastic fibers, for example polyester fibers, or glass microfibers, for example as glass microfiber paper with fibers made of borosilicate glass, preferably without a binder.

The filter wall can be flat, cylindrical or conical and flat in itself or provided with accordion-like folds.

An increasing filter density towards the inside of the bag favors a successive separation of the aerosol droplets from the gas flow.

The density of the filter wall can increase continuously or in discrete steps in a thickness direction from the outside of the bag to the inside of the bag. The density of the filter wall on the inside of the bag can be in a range from 20 to 80 kg / m3, in particular 30 to 40 or 50 kg / m3. The density on the outside of the bag can be in a range from 10 to 40 kg / m ³ , in particular 15 to 30 kg / m ³ . The gradient of the increase in density from the outside of the pocket to the inside of the pocket can be linear or exponential. If the density increases in discrete steps, the filter wall preferably has at least 2, 3, 4 or 5 steps over its thickness.

The filter wall can be vertical at any point or, in a direction facing away from the frame, be inclined downwards at a predetermined angle in order to ensure safe and rapid drainage and dripping of the absorbed liquid from a filter bag. Particularly preferably, the filter pocket essentially has a vertically downward direction of extent from the frame. This can prevent the liquid separated from the gas stream from settling in Can accumulate depressions or on horizontal plateaus. The filter wall can be arranged at any point at an angle of a maximum of 5 °, 10 °, 20 °, 30 °, 45 °, 60 °, 70 °, 80 ° or 89 ° to the vertical.

The filter pocket can taper in a direction of extent that runs, in particular, orthogonally to the exit surface and points away from the frame. The filter pocket can have a drip edge, which further promotes dripping of the liquid droplets. The filter pocket is preferably round or V-shaped in cross section. A V-shaped filter bag can consist of two filter walls which are connected to one another at their lower ends and can form a drip edge. At the end faces of the filter pocket, at a front and at the rear end of the filter pocket, viewed in a longitudinal direction, the filter walls can be connected directly to one another, or end walls for connecting the two filter walls can be provided. At the upper ends, the filter walls of a filter pocket can each be connected to a filter wall of an adjacent filter pocket along the longitudinal direction of the filter pocket. Alternatively, the filter pocket can be designed like a cartridge, in particular with a cylindrical or conical filter wall.

A plurality of filter pockets can be arranged parallel to one another along the longitudinal direction arranged parallel to the exit surface.

Furthermore, the frame of a filter pocket can be formed by rigid profiles. Two adjoining filter walls of two filter pockets can have a common rigid profile as part of the respective frame. The profiles, as well as the other sections of the frame, can be made of plastic, aluminum, steel or another solid material. The filter pockets can be connected to the profile by clamping, riveting, screwing or adhesive connections. For this purpose, the profile can enclose the end of the filter wall or the ends of the two filter walls of the two different filter pockets in a U-shape on at least three sides.

The filter pocket (s) is / are preferably encapsulated with a plastic frame in the area of the outlet opening (s) in order to achieve optimum tightness. A metal profile can be cast into the plastic frame as reinforcement.

The jointly used profiles of two adjacent filter pockets can run along the longitudinal direction of the filter pockets. For this purpose, the profiles can be arranged in a common outer frame which encloses several filter pockets and carries the individual profiles at a distance from one another. The frame of a filter bag can accordingly consist of two sections of the outer frame orthogonal to the longitudinal direction and two profiles along the longitudinal direction.

The ratio of the length of the filter pocket in the longitudinal direction to the width of the filter pockets orthogonal to the longitudinal direction at their widest point in each case can be in a range from 1 to 20, preferably up to 10.

Furthermore, a collecting container can be provided for aerosol that has been filtered out and dripping down from the filter bags. Such a collecting container is arranged below the filter bags and can easily be removed from the outside of the filter device in order to empty it. Alternatively, the collecting container can be emptied via a drain. The drain can be opened or closed via a valve, for example. If several filter stages arranged in series as seen in the flow direction of the gas are provided, a common collecting container or separate collecting containers can be provided for the different filter stages.

An upstream filter stage with a filter or separation cassette, for example with a filter material made of stainless steel mesh or knitted fabric, woven or fleece-like stainless steel fibers, can be provided, the upstream filter stage being connected to the inlet chamber upstream. In this case, the gas flow first flows through the upstream filter stage before it flows through the filter pockets. The aerosol loading of the gas flow can already be reduced in the upstream filter stage. This can prevent clogging or overloading of the filter bags. Any solids transported in the gas flow, such as chips and dust, can also be filtered out in an upstream filter stage. The filter material can be layered single or multi-thread, preferably double-thread, stainless steel fibers, in particular a knitted fiber fabric, with a thread diameter of 0.05 to 0.5 mm, in particular 0.1 to 0.3 mm, approximately 0.14 mm, and a density of 100 to 500 kg / m ³ , in particular 200 to 300 kg / m ³ , for example 240 or 250 kg / m ³ .

In addition, a downstream filter stage with a fine filter can be provided. This can be directly connected to the frame or downstream to the outlet chamber. In the outlet chamber, which can either be connected directly to the outlet opening or to the frame, or to the downstream filter stage, the gas flow from several filter pockets can be brought together again before it enters the fine filter. Very fine aerosol droplets or particles can be filtered out via the fine filter before the gas flow is returned to the ambient air. The fine filter can have a filter area of 0.1 to 30 m ² and can contain a glass fiber fleece or glass fiber paper (micro glass fiber paper), in particular a single-layer and hydrophobically surface-treated glass fiber fleece or paper, which can be folded flat or like an accordion and inserted into a frame. In the frame, the filter material can be potted and sealed with a sealing compound or potting compound. The frame can be rectangular, square, or pyramidal.

A filter device according to the invention can be used as an integral part of a production machine for machining components or can be connected to such a production machine by means of hoses or pipes.

The filter device can preferably be designed as a mobile filter system that can be connected to a production machine with hoses. In such a case, the filter device can also have a displacement mechanism, for example rollers or wheels. In the case of a stationary embodiment of the filter device, on the other hand, it can be advantageous to connect the filter device with pipes to the production machine or to integrate it into it.

The filter device preferably has between one and 20, in particular between 5 and 10, filter pockets. One or more filter modules are preferably formed, each comprising 4 or 8 filter pockets. All of the filter pockets of the module or modules can be cast into a common frame in the area of their outlet openings.

The angle between the two filter walls of a V-shaped filter pocket can be less than 45 °, in particular less than 30 °, in particular less than 20 ° or 10 ° and, for example, 5 °, 10 °, 15 °, 20 ° or 30 ° be.

A filter area of a filter pocket, ie a surface of the or all of the filter walls of a filter pocket, can be between 0.25 m ² and 5 m ² , preferably between 0.1 m ² and 0.5 m ² , or 0.3.0, 4, 0.5, 0.6 or 0.7 m ² .

The height of a filter pocket is preferably between 100 mm and 1000 mm, for example 300, 500 or 700 mm. The width of the filter pocket is preferably 200 mm to 800 mm, more preferably 300 mm to 600 mm.

A suction device, for example a fan, of the filter device can be arranged downstream of the outlet chamber in order to allow the gas stream to flow through the filter device. The suction device can be designed to convey a gas flow, in particular an air flow in the range from 200 to 100,000 m ³ / h.

• 1 zeigt schematisch eine erfindungsgemäße Filtervorrichtung,
• 2 zeigt eine Anordnung mehrerer Filtertaschen an einem Rahmen,
• 3 zeigt eine perspektivische Darstellung des Rahmens, und
• 4 zeigt ein zwei Filtertaschen verbindendes Profil.

In the following, exemplary embodiments of a filter device according to the invention are explained in more detail with reference to figures.

• 1 shows schematically a filter device according to the invention,
• 2 shows an arrangement of several filter bags on a frame,
• 3 shows a perspective view of the frame, and
• 4th shows a profile connecting two filter pockets.

An exemplary filter device according to the invention 2 includes in one housing 14th several filter bags arranged parallel to one another 4th , as in 1 shown. Each filter pocket has 4th at least one filter wall 6th on. In the embodiment shown, each filter pocket has 4th two V-shaped arranged filter walls 6th on that at a lower end of the filter bag 4th on an edge 4a converge and are connected there. The filter bags 4th form an outlet opening at their upper ends 7th on which the filter walls 6th end and end gas-tight with a frame 24 are connected. An entry chamber 8th closes gas-tight on the frame below or upstream 24 at. Above the frame 24 an exit chamber closes 10 gastight to the frame 24 at.

Any filter bag or filter wall 6th has an upper edge portion which runs along a circumference of the outlet opening and forms this and with the frame 24 is connected gas-tight. The filter bag or filter wall 6th can in the area of this edge section with the frame 24 be potted from plastic material. For this purpose, the edge section is placed in a form that has the contour of the frame 24 possesses, and potted with plastic, at the same time the frame is made and a gas-tight connection and mechanical fixation of the filter bag with and on the frame takes place.

Below the filter bags 4th is a collecting container 12th arranged. The collecting container 12th serves to remove the filter bags 4th to collect dripping drops of liquid. The collecting container preferably has 12th furthermore a drain (not shown here), preferably at its lowest point, with which the collected liquid can be drained off. Alternatively, the collecting container 12th out of the case 14th the filter device 2 pulled out to empty it. In the illustrated embodiment is in the housing 14th furthermore an upstream filter stage 15th with a filter cartridge 16 arranged to be a Connection element 17th connects. To the connection element 17th For example, an air line can be connected via the air from a suction room or area to the filter device 2 to be led. The air line can be a pipe or a hose, for example. The filter device 2 but can also be integrated directly into a system that includes a room whose air has to be cleaned. The connection element can accordingly 17th also directly adjoin a room, the air of which is to be filtered.

In the embodiment shown, there is also a downstream filter stage 18th provided downstream of the frame 24 (or downstream of the exit chamber 10 ) is then arranged. Downstream of the exit chamber 10 is a suction device in the form of a fan 20th arranged. The downstream filter stage 18th includes a fine filter and is supported by a holder 22nd in the case 14th held.

During operation, the fan is used 20th an air flow is sucked in through the connection element 17th into the filter device 2 entry. This is followed by a homogenization section 25th arranged. In the homogenization section 25th the air flow is evenly distributed over the flow cross-section, so that the upstream filter stage 15th with the filter cassette 16 is evenly perfused. The filter cartridge 16 can be filled with coarse fibers, for example with woven or non-woven metal fibers, on which the first aerosol droplets and possibly also solid particles are filtered out. The absorbed liquid can be taken from the fibers to the collecting container 12th drops. As an alternative to the embodiment shown, in which a common collecting container 12th for the upstream filter stage 15th and the filter bags 4th is provided, several, separate collecting containers for the filter bag 4th and the filter stage 15th be provided.

After passing through the upstream filter stage 15th the air stream flows into the inlet chamber 8th in which the filter bags 4th hang. The filter bags 4th are flowed through by the air flow from the outside to the inside. The filter walls 6th the filter bags 4th are made of a fiber material that is wetted by the aerosols carried by the air flow. The fibers on the inside of the filter walls 6th are arranged more densely than on the outside. Droplets agglomerate into larger drops and flow along the filter wall 6th downwards and drip at the latest at the lower edge of the filter bag 4th into the collecting container 12th away.

In the case shown, the filter pockets 4th a V-shaped cross-section. The tip of the V forms the lowest end of the filter pocket 4th . The filter walls 6th the filter bags 4th thus point downwards along their entire extent. In this way, the drops of liquid can run down unhindered, and the lower end of the V forms a drip edge. The tops of the filter bags 4th are in the frame 24 held. There are two filter walls 6th two adjacent filter pockets 4th by means of the frame 24 connected with each other. Furthermore, the frame and the filter bags close the entry chamber 8th so from the exit chamber 10 so that the air flow only through the filter bags 4th can flow.

In the exit chamber 10 the air flow from the different filter bags is combined 4th and then flows through the fine filter 18th . The fine filter 18th can have one or more filter walls by means of which fine aerosols are filtered out of the air flow so that a desired or prescribed air quality is achieved. The air flow then passes through the fan 20th and is released to the environment or a predetermined space.

In 2 is the suspension of the filter bags 4th shown in detail. In the embodiment shown, the filter bags hang 4th in a frame 24 in the direction of the extension direction E. . The direction of extension E. preferably points vertically downwards. Alternatively, the direction of extension E. run at an angle to the vertical that can be up to almost 90 °, provided that it is ensured that each filter wall still has a slope.

In the perspective view of the frame 24 in 3 it can be seen that there are two walls 6th two filter bags 4th from a common profile 26th being held. The profiles 26th run along a longitudinal direction L. the filter device 2 . An exemplary cross-sectional representation of such a profile 26th is in 4th shown. The profiles 26th form together with an outer frame 28 the frame 24 . Here are the profiles 26th equidistant from one another in the outer frame 28 attached. The respective outer filter walls 6th of the outermost filter pockets 4th are at their top directly with the outer frame 28 tied together.

The profiles 26th preferably grip around the ends 34 second filter bags 4th with a U-shaped profile and press them together, for example via the clamping effect of the profile, gluing, clamping elements or screw or rivet connections. Alternatively, a plastic frame is cast with the filter material. That’s the end of it 34 the filter bags 4th tightly connected so that the airflow over the outside of the bag 30th the filter bags 4th through the filter walls 6th to the inside of the bag 32 flows. The inside of the bag 32 has the highest filter fineness and the outside of the bag 30th the lowest filter fineness. In between, the density can be along the thickness D. the wall 6th change continuously or discretely in steps, for example by means of several filter layers that follow one another or are laminated on one another and each have a certain filter fineness.

It is within the scope of the invention that the filter wall or walls of the filter pocket (s) consist of a filter material which is intended and suitable for separating liquid aerosol particles.

List of reference symbols

2

Filter device

4th

Filter bag

4a

Edge

6th

Filter wall

7th

Outlet opening

8th

Entry chamber

10

Exit chamber

12th

Collecting container

14th

casing

15th

upstream filter stage

16

Filter cartridge

17th

Connection element

18th

downstream filter stage

20th

Fan, suction device

22nd

bracket

24

frame

25th

Homogenization section

26th

profile

28

Outer frame

30th

Outside of the pocket

32

Inside pocket

34

End of the filter bag

E.

Direction of extension

L.

Longitudinal direction

D.

thickness

Claims (10)

Filter device for separating liquid aerosols from a gas stream with a sack-like filter pocket (4) which has an outlet opening (7) and which has a filter wall (6) permeable to the fluid flow with a pocket inside (32) and a pocket outside (30), a frame (24) which is gas-tightly connected to a peripheral edge of the outlet opening (7), an inlet chamber (8) which encloses the filter pocket (4) and adjoins the frame (24) in a gas-tight manner and an outlet chamber (10) adjoining the frame (24) and the outlet opening (7) in a gas-tight manner, wherein the pocket outside (30) forms an entry surface and the exit opening (7) forms an exit surface for the gas flow into and out of the filter pocket (4), wherein the filter wall (6) of the filter bag (4) has a first density on the outside of the bag (30) and a second density on the inside of the bag (32) which is greater than the first density. Filter device according to Claim 1 , characterized in that the density of the filter wall (6) increases continuously or in individual steps over the thickness D of the filter wall (6) from the outside of the bag (30) to the inside (32) of the bag. Filter device according to one of the preceding claims, characterized in that the filter wall (6) is inclined vertically at each point or, in a direction pointing away from the frame (24), downwards at a predetermined angle. Filter device according to one of the preceding claims, characterized in that the filter pocket (4) tapers in an extension direction (E) pointing away from the frame (24). Filter device according to one of the preceding claims, characterized in that a plurality of filter pockets (4) are arranged parallel to one another along a longitudinal direction (L) arranged parallel to the exit surface. Filter device according to one of the preceding claims, characterized in that the or each filter pocket (4) is cast with the frame (24) in the area of the outlet opening (7), the frame (24) being made of a plastic material and cast reinforcing elements made of metal or contain plastic. Filter device according to one of the preceding claims, characterized by a collecting container (12) for liquid aerosol that has been filtered out and dripping down from the filter pockets (4). Filter device according to one of the preceding claims, characterized by an upstream filter stage (15) which adjoins the inlet chamber (8) upstream. Filter device according to one of the preceding claims, characterized by a downstream filter stage (18) with a fine filter, the downstream filter stage (18) connecting downstream to the outlet chamber (10) or downstream to the outlet opening (7). Filter device according to one of the preceding claims, characterized in that a suction device (20) is arranged downstream of the outlet chamber (10) in order to cause the gas stream to flow through the filter device.

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