DE10154793A1 - Process for extracting, conveying and collecting dusty and fine-grained material and device - Google Patents

Abstract

The invention relates to a method for suctioning off, conveying and filtering material obtained during machining processes, in particular flammable, dusty or fine-particle material, for example made of aluminum, magnesium, graphite and the like, which is sucked in, brought into contact with a liquid and then collected. The invention also relates to an apparatus for performing the method. DOLLAR A The invention is characterized in that the liquid is guided as a liquid flow into a mixing area, that the sucked-in material is guided in the mixing area in such a way that it impacts the liquid flow, penetrates into the liquid flow and is carried along by the liquid flow.

Description

The invention relates to a method for suction, conveying and Collecting goods from processing processes, in particular flammable, fine-particle, dusty or fog-shaped material made of metal, aluminum, magnesium, graphite, Fluid and / or the like sucked in an air stream, brought into contact with a liquid and afterwards is collected. The invention also relates to devices to carry out the procedure.

Such a method with an associated device is become known from DE 38 38 395 A1. This becomes filtering material by means of a nozzle with a liquid sprayed. However, it has been shown that especially at chemical reactions-prone goods, such as in particular Magnesium and aluminum, not by the known method with 100% certainty that the Well completely coated or wetted by the liquid becomes. An incomplete wetting or coating of Aluminum or magnesium dust can become undesirable, violent cause chemical reactions. Especially in connection with Oxygen is created in highly explosive, self-igniting Gas mixtures. The known method is also not suitable for the extraction of fluids, especially fluid mists.

The present invention is therefore based on the object a known method and a known device such further education that ensures that all Particles of the material to be filtered completely with the appropriate liquid can be coated. Because of a such coating become undesirable chemical Reactions prevented.

A method mentioned at the outset is used to solve the problem proposed that the Liquid as a liquid flow in a mixing area is carried out so that the suctioned material in the mixing area that it impacts the flow of liquid into which Liquid flow immerses and from the liquid flow is carried along. This has the advantage that due to the Immersing the individual particles of the sucked material in the liquid flow completely with the liquid is wetted or coated. An unwanted reaction from the good with air and especially with oxygen can therefore no longer take place. In addition, so can Fluids and fluid mists are suctioned off in the liquid be bound.

The liquid flow advantageously flows with a large volume and a low speed. In the area of the inflow, the liquid flow should largely maintain its flow contour and not tear off. An advantageous liquid volume flow is 4 to 8 l / min. based on an air volume flow of 150-400 m ³ / h. Favorable values result from appropriate ratios of liquid volume flow to air volume flow.

The speed of the air flow and thus the Velocity of the particles carried by the air flow of the suctioned material is advantageously 30 to 40 m / s. So in the mixing area it slows down Liquid immersed good its speed up the slow flow rate of the liquid flow.

Advantageously, the liquid flow and the Air flow guided such that the particles of the sucked in Good things hit the liquid flow so that the If possible, do not spray liquid into a mist. this has the advantage that complex measures for filtering Liquid mist is eliminated.

In another embodiment of the invention provided that the liquid stream containing the material and the airflow following the mixing area at least one filter, in particular through a sieve basket in which the goods are collected. As a result of that both the liquid flow and the air flow are filtered is ensured that everything in the air flow and Particles of the good present in the liquid flow filtered out and collected.

Oil and in particular is advantageously used as the liquid Cooking oil used. Especially in connection with a good Made of aluminum and / or magnesium, edible oil has become proven advantageous. It has the advantage of being one the immersion of the particles enables and secondly not tends to atomize. It is also environmentally friendly.

Depending on the chemical nature of the good for example, water or other suitable ones Liquids come into question. Water is suitable in Connection with a good that consists of steel chips or steel dust is formed.

If the material to be extracted is a fluid or a fluid mist, the liquid can have the same chemical nature as that Have fluid. For example, oil mist can be extracted be by the inventive method in the oil existing liquid penetrates and combines with it or mixed.

The above object is also achieved by a device for Implementation of the procedure described above solved. The device sees the one to be promoted or the material to be filtered and the intake line guiding the air flow in front. The suction line is characterized by the fact that it has a first knee or arch-shaped mixing section, that in the area of the mixing section or upstream of the Mixing section an inlet for the liquid flow in the Intake pipe is provided and that the mixing area located within the mixing section.

This has the advantage that due to the redirection of the good leading airflow due to its higher specific weight and its inertia not redirected is, but collides against the liquid flow in this immersed and carried along by it. The airflow will positively guided above the liquid flow.

According to the invention, it is ensured that all particles of the goods due to immersion in the liquid flow be coated with liquid.

In addition, the opposite of the incoming air flow Wall or the outer radius of the arcuate tube section against wear from impacting particles of the goods protected. The particles do not hit the wall of the pipe section, but on the liquid flow.

The fact that the mixing area within the arc Pipe section is also advantageously due a suitable curvature of the pipe section avoided that the liquid stream atomizes. The formation of a undesirable liquid mist is therefore prevented. Ideally, the flow conditions are in the range of arcuate or knee-shaped pipe section and in the Pipe section subsequent area laminar.

Advantageously, the suction line sees both in particular in the area upstream of the knee or arch Pipe section as well as in the area of the knee or arcuate pipe section a round cross section. This results in particularly favorable ones Flow conditions within the intake line; the education an undesirable liquid mist is reduced.

In a further, particularly preferred embodiment of the The invention provides that the first knee or arcuate tube section a second knee or arcuate pipe section is arranged downstream. About one second such pipe section is achieved that the Airflow is redirected again, still in the airflow existing particles of the material to be filtered are directed in such a way that they are in the second knee or arc tube section meet again in and in the liquid flow plunge. In the second knee or arch Accordingly, a second mixing area is provided in the tube section, in the still existing one, still in the air flow Particles are mixed into the liquid stream.

An advantageous embodiment results when the Suction line after the second knee or arch Pipe section runs largely vertically.

The first and possibly also the second knee or arch Pipe section advantageously has an elbow 90 ° on. It is conceivable that even larger angles, in particular can be provided up to 120 °. The angle to choose depends on the particle size of the material to be filtered, of the flow and flow rate of the Airflow as well as the flow and the Flow rate of the liquid flow.

The task mentioned above is also a Device with a leading the goods and the air flow Intake pipe released, which is characterized in that the Intake line having the mixing area Mixing section has that in the area of the mixing section or an inlet for the upstream of the mixing section Liquid flow is provided in the suction line, wherein in the mixing section at least two in the direction of flow successive guiding means for guiding the Liquid flow are arranged such that that of the Incoming liquid flow through the first Guide means flows and affects the second guide means pours, the airflow between the first and the can flow through second guide means. Between the two Fluid is therefore a kind of passage or gap available. The passage is determined by the flow of liquid overflows. The air flow passes through the liquid flow in the Area of the passage. The good in the air flow therefore meets the liquid flow, immerses in it and is carried by it. In that the airflow penetrates the liquid flow becomes the liquid flow sprayed, a mist formation of the liquid flow does not occur, however. By providing several, in Flow direction consecutive guide means the air flow leading the material penetrates the Liquid flow multiple times, which can ensure that all particles of the good in the liquid flow plunge.

Such a device has the advantage that it especially for the extraction of very fine dusts and Liquid mist is suitable. Especially very fine Particles of the material appear when the product is penetrated several times Liquid flow into and out of this one carried.

The liquid stream advantageously pours over the entire width of the mixing section from a guide means to another management tool. This has the advantage that the forced air flow leading the material, the Liquid flow must pass.

According to the invention, it is advantageously conceivable that the Management means designed as management levels and such are arranged that the liquid flow facing Sides of the guide planes and the longitudinal axis of the Mixing section each an angle of less than 90 °, and in particular an angle in the range from 60 ° to 85 °, lock in. Especially when flowing through the Liquid flow from top to bottom over the Such an arrangement has been found to be special in guiding means proven positive.

The guide means advantageously overlap Looking at each other in the longitudinal direction of the mixing section. This ensures that the liquid flow from a guide means on the in the direction of flow guide means behind it pours.

The guide means in the mixing area are according to the known ball track principle arranged. It would be a bullet Gravity following from an upstream Guide means on a guide means arranged behind to meet. She would follow the inclination of this guide, and from this guide means to another guide means to meet. The line of motion of the ball therefore represents one Zigzag line.

The stated task is also achieved by a device in particular to carry out the invention Process, with a leading the good and the air flow Intake pipe, solved, which is characterized in that the suction line has a mixing area Mixing section has that in the area of the mixing section or an inlet for the upstream of the mixing section Liquid flow is provided in the suction line and that upstream of the mixing section and preferably also flow guide means are provided upstream of the inlet, that redirect or deflect the airflow in such a way that the the entrained air flow on the liquid flow bounces, immersed in the liquid flow and from which Liquid flow is carried. This will be a targeted penetration of the goods into the liquid flow allows. In particular, the angle at which the Good penetration into the liquid flow is relatively accurate be predetermined. The flow guide can for example, be wing or spoiler-like. at suction lines with a round cross-section can do this Flow guiding means as circulating at least in sections Beading. With a rectangular cross section Intake lines can be the flow guide as a baffle or be designed as a guide wing.

An advantageous embodiment of the invention provides that downstream of the mixing area or the mixing section Expansion of the intake line is provided. Such a widening the cross section of the suction line the advantage that after immersing the goods in the Liquid flow the air flow quickly calms down. hereby will mix and swirl liquid in avoided the airflow.

According to the invention, it can advantageously be provided that the suction line upstream of the mixing section largely runs vertically. This causes the gravity to act Velocity of the particles entrained in the air flow of the goods to be filtered. The impact and Immersion of the goods in the liquid is thus improved.

In another embodiment of the invention downstream of the first or possibly the second knee or arcuate pipe section a collecting container for the goods arranged.

In one embodiment, the collecting container can be used as Be sieve basket through which the containing the material Liquid flow and also the air flow is guided. Due to the passage of both streams through the strainer ensures that everything in the airflow as well as in the Liquid flow existing particles of the material to be filtered pass the sieve basket. Accordingly, it is excluded that Particles of the material to be filtered leave the device can.

In another embodiment of the invention is as Collection container a cell of a lock, especially one Cell wheel lock, provided. This embodiment has the Advantage that due to the presence of the lock Device can work continuously without Removing the filtered goods shut down the system must become.

In a further advantageous embodiment of the invention the liquid flow containing the material hits the in the existing container. This has the advantage that already collected goods do not dry out and undesirable can enter into chemical reactions.

According to the invention it is also conceivable that the screen basket over a filter device connected to a vacuum source is. This ensures that there is in the screen basket located particles on the edges or on the bottom of the Secure the strainer basket. Furthermore, contrary to expectations Sieve basket passing particles due to the filter device do not get into the environment.

To separate liquid and filtered material the sieve basket is above one Liquid collection container arranged. So that in the Excess liquid in the strainer basket Drain the liquid collection container. Dusts of the good that with the liquid in the liquid collection container get, advantageously sit on the bottom of the Liquid collection container as sludge.

To the liquid to the mixing section or to the feed a screw pump will advantageously promote used. The screw pump has the advantage that the liquid does not foam up, causing undesirable Liquid mists in the intake line can lead. Further become long-chain molecules of the liquid, like those in oils are present, not separated by the pumping process.

Further advantageous configurations and details are the following description can be seen in the invention based on the embodiments shown in the drawing is described and explained in more detail.

Show it:

Fig. 1 is a schematic representation of a first apparatus according to the invention in side view,

Fig. 2 shows a section of the intake pipe of the apparatus of Fig. 1,

Fig. 2a shows an alternative to Fig. 2 section of the intake pipe of the apparatus of Fig. 1,

Fig. 3 shows a section through Fig. 2 along the line III,

Fig. 4 is a schematic representation of a second device according to the invention in side view,

Fig. 5 shows the mixing section of the suction pipe of the device according to Fig. 4,

Fig. 6 is a section through FIG. 5 taken along line VI

Fig. 7 is a schematic representation of a third embodiment of the invention, and

Fig. 8 shows a pipe section of a device according to the invention.

Fig. 1 shows an inventive device 10 for filtering in machining processes accumulating combustible dusty and feinspanigem Good 11 such as, aluminum or magnesium. A suction line 12 is shown , which provides a line branch 14 , on the line sections 16 and 18 of which a flexible suction line 20 and 22 is arranged. The free ends of the suction lines 20 , 22 have suction heads 24 of different designs. In the suction head 24 of the suction line 22 is, for example, a directly connectable to a grinding or polishing machine suction head 24.

The suction line 12 leads to a collecting container 26 which provides a cover 30 which is connected to the end of the suction line 28 in an airtight manner. The cover 30 as such is air-impermeable.

The collecting container 26 is designed as a strainer basket 27 , which provides air-permeable and very fine sieve material on the bottom surface and on the outer surface.

The sieve basket 27 is arranged above a liquid collection container 32 . A vacuum generator 36 is arranged above the screen basket 27 via an air filter device 34 .

The device 10 provides a vacuum housing 62 within which the strainer basket 27 and the liquid collection container 32 are accommodated.

The suction line 12 provides a mixing section in the form of an arc section 38 , on the outside of which an inlet 40 for liquid 42 is arranged, which is conveyed out of the liquid collecting container 32 via a screw pump 45 . The liquid 42 consequently pours into the suction line 12 within the arc section 38 . The liquid flow running within the suction line 12 bears the reference symbol 44 . The liquid stream 44 flows over a largely horizontal pipe section 46 and pours into the sieve basket 27 via a second curved section 48 .

The liquid is advantageously oil, with edible oil especially for goods containing aluminum and / or magnesium suitable.

During operation of the device 10 , an air flow is generated via the vacuum generator 36 on the suction heads 24 and in the suction line 12 , which is indicated by arrows 50 . The air flow 50 carries with it the material to be conveyed and collected in the form of dust and chip-shaped aluminum or magnesium particles 11 . The particles 11 carried in the air stream 50 meet the liquid stream 44 in a mixing area 56 within the arc section 38 , which is why the arc section 38 forms the mixing section. Due to the relatively high speed of the particles 11 carried by the air flow and their inertia, the particles 11 penetrate into the liquid flow 44 and are guided or conveyed by it along the pipe section 46 and the curved section 48 . The particles 11 reduce their speed to the flow speed of the liquid stream 44 . The speed of the air flow 50 does not decrease or only insignificantly.

The liquid stream 44 carrying the particles 11 pours into the sieve basket 27 via the inner side of the arc section 48 . Due to the fine-meshed sieve material, the carried material 11 collects on the bottom of the sieve basket 27 and on its walls.

The liquid drips from the strainer basket 27 into the liquid collecting container 32 . Very fine particles, in particular dusts of the material 11, pass through the sieve basket 26 with the liquid and collect as sludge 54 in the area of the bottom of the liquid collection container 32 .

In the Figs. 2 and 3 of the arc portion 38 is shown with the inlet 40 increases. It can be clearly seen how the liquid 42 pours from the inlet 40 into the curved section 38 . The liquid 42 is introduced into the section 38 in such a way that if possible the liquid is not atomized. Rather, a liquid flow 44 with ideally a closed surface is formed within the sections 38 , 46 and 48 of the suction line 12 . The flow conditions of liquid stream 44 and air stream 50 are preferably laminar in the pipe sections 38 , 46 and 48 . The liquid 42 preferably flows into the arc section 38 at a relatively low flow rate of 0.1-0.2 m / s and a volume flow of approximately 6 l / m. The flow contour of the liquid flow preferably remains stable and is not torn off. At the flow rate mentioned, the speed of the air flow is approximately 30-40 m / s and the volume flow of the air is advantageously 150-400 m ³ / h and in particular 200-300 m ³ / h.

Because of the higher specific weight and the inertia of the particles 11 carried in the air flow 50 , which have a speed of approximately 20-25 m / s, the particles 11 are not deflected along the arc section 38 . The particles 11 impinge on the volume flow 44 in the mixing region 56 . The air flow 50 , without the entrained particles, is deflected on the surface of the liquid flow 44 and preferably flows in a laminar manner in the tube area 46 above the liquid flow 44 . The curvature of the curved section 38 and the location at which the inlet 40 is arranged is advantageously chosen so that as little turbulence as possible and very little or ideally no swirling and atomization of the liquid flow 44 takes place in the suction line 12 .

The liquid or oil 42 should have a consistency such that it enables the sucked-in material to penetrate and does not tend to atomize.

As can be seen in FIG. 3, the suction line 12 and in particular the curved section 38 has a circular cross section. The air flow 50 is deflected by 90 ° in each case via the arc sections 38 and 48 . According to the invention, it is also conceivable to provide a deflection by more than 90 °, for example by up to 120 °.

If, however, particles of the sucked-in material do not penetrate into the liquid flow 44 in the mixing area 56 , but are carried along with the air flow 50 in the pipe sections 46 and 48 , then they enter the liquid flow 44 in the downstream section 48 . FIG. 2 clearly shows that the liquid stream 44 pours over the entire cross section of the suction line in the region of the second arcuate section 48 . Due to its low flow velocity, the liquid flow 44 has a smooth course, the air flow 50 again meeting the liquid flow 44 in a second mixing area 57 . Unwetted material 11 not contained in the liquid flow 44 also penetrates into the liquid flow 44 at this point.

The invention has the advantage that ensures is that the aspirated material penetrates into the liquid and thus completely wetted or coated by the liquid becomes. An undesirable chemical reaction with the goods oxygen in particular is thus reliably prevented.

The supply of the liquid flow 44 in the arch section 38 also has the advantage that the wall section of the arch 48 opposite the incoming air flow 50 and lying below the mixing region 56 is protected from material 11 hitting the wall. This reduces the wear on the arc section 38 .

In the largely horizontal tube section 46 , the air flow 50 is forcibly guided as parallel as possible to the liquid flow 44 , so that vortex formation and atomization of the liquid are prevented. The avoidance of atomization of the liquid has the advantage that it is not necessary to filter out a liquid mist.

In FIG. 2a, which shows an alternative embodiment to FIG. 2, it is provided that upstream of the mixing section 38 and also upstream of the inlet 40, a flow guiding means 52 is provided in the form of a bead, which deflects the air flow 50 in such a way that the entrained air Good 11 impinges on the liquid flow 44 at an advantageous immersion angle. Instead of a bead 52 , a wing or spoiler that achieves a corresponding effect can also be used. In FIG. 2a, in contrast to FIG. 2, the suction line downstream of the mixing area 56 or the mixing section 38 has an expansion 53 . The expansion results from the diameter b of the horizontally running pipe section 46 , which is larger than the diameter a of the vertically running pipe section 46 above the flow guide means 52 . Such a widening 53 , which increases the cross section of the suction line, has the advantage that after the material 11 is immersed in the liquid flow 44 , the air flow 50 quickly calms down.

The embodiments of the invention shown in FIGS. 4 to 8 can also be designed with flow guide means 52 and / or widenings 53 .

The use of a screw pump 45 also helps to prevent foaming and atomization of the liquid. The liquid is also prevented from changing its chemical properties. In particular when using oil as a liquid, other types of pumps, for example a centrifugal pump, can lead to undesirable chemical changes in the oil; in particular, long-chain molecules can be separated.

The entire air flow 50 entering the strainer basket 26 passes through the bottom as well as the walls of the strainer basket 27 . This ensures that no material carried by the air flow 50 can get out of the screen basket 27 . After passing through the strainer basket 27 , the air flow is identified in FIG. 1 by the reference number 58 . For safety reasons, the air stream 58 passes through the air filter device 34 before it is fed to an air outlet 60 via the vacuum generator 36 . This ensures that no particles of the extracted material 11 can be present in the exhaust air.

According to the invention, the particles 11 collecting in the sieve basket 27 are completely coated with the liquid. An undesirable chemical reaction of the particles 11 with oxygen in particular cannot therefore take place.

The device 90 shown in FIGS. 4 to 6 essentially corresponds to the device 10 shown in FIGS. 1 to 3. Corresponding components are provided with corresponding reference symbols. In the device 90, the suction line 12 has a mixing section 92 , the longitudinal axis of which extends vertically. The mixing section 92 has an inlet 94 for the liquid flow 42 on the upstream side. According to the device 10 , the device 90 can provide that a further inlet 40 is provided in the curved section 38 . A branch 96 from the liquid flow 42 to the inlet 40 is therefore shown in dashed lines.

The mixing section 92 shown enlarged in FIG. 5 provides a total of four guide means arranged one behind the other in the flow direction in the form of guide planes 98 , 100 , 102 and 104 for guiding the liquid flow, which is identified within the mixing section by reference number 106 . As can be seen from FIG. 6, the mixing section 92 is rectangular in cross section and has four side walls 108 , 110 , 112 and 114 . The guide levels 98 and 102 are arranged on the side wall 108 and the guide levels 100 and 104 on the side wall 110 . The guide planes 98 , 102 and 100 , 104 extend over the entire width of the side walls 108 and 110, which is transverse to the longitudinal axis 116 . The guide planes 98 , 100 , 102 and 104 are arranged on the side walls 108 and 110 such that they and the longitudinal axis 116 of the mixing section 92 each enclose an angle of approximately 60 °. The intersection lines of the guide planes 98 , 100 , 102 and 104 with the respective side walls 108 and 110 run parallel to one another. The guide levels 98 and 102 and the guide levels 100 and 104 are each arranged parallel to one another. A gap d is provided between each two guide planes one behind the other in the flow direction.

As shown in FIG. 5, the liquid flow 106 coming from the inlet 94 flows over the guide plane 98 and pours over the free edge 118 of the guide plane 98 onto the guide plane 100 . Because of the herringbone-like, mutually overlapping arrangement of the guide levels 98 , 100 , 102 and 104 , the liquid flow 106 on the guide level 100 changes its flow direction. It pours over the free edge of the management level 100 onto the management level 102 . From there it pours onto the guide level 104 , from which it leaves the mixing section 92 .

The arrangement of the guide planes 98 , 100 , 102 and 104 corresponds to the arrangement of guide rails of a ball track. A ball placed on the management level 98 would roll from this onto the management level 100 , from this onto the management level 102 and from this onto the management level 104 . The arrangement can therefore also be referred to in principle as a ball track.

The air stream 50 carrying the material 11 strikes the liquid stream 106 in the region of the guide level 98 . Due to the high weight and the inertia of the good 11 , it penetrates into the liquid flow 106 . When passing through the mixing section 92 , the air volume flow 50 must penetrate through the gap d between the respective guide planes one behind the other. The air flow 50 with the material 11 contained therein passes the liquid flow 106 several times. All of the particles 11 contained in the air stream 50 are taken up by the liquid stream 106 . Downstream of the mixing section 92 , the air stream 50 contains no material 11 . The good 11 is in the liquid flow 106 .

When passing the air stream 50 by the liquid flow 106, it comes to splashing of the liquid flow 106th However, an undesirable, fine atomization of the liquid flow 106 does not occur. After leaving the mixing section 92 , the liquid flow 106 carrying the material 11 and the air flow 50 calm down, liquid drops contained in the air flow 50 mix with the liquid flow 106 .

The mixing area 92 shown in FIGS . 4-6 is particularly suitable for dust-like material. It is also suitable for mixing mist-like material with the liquid flow or for binding it in the liquid flow. The liquid flow can be made of an identical substance to the mist-like material.

Furthermore, the mixing section 92 is suitable for extracting sparks which can arise, for example, during metalworking. Water is recommended as the liquid.

In FIG. 6, the mixing area in which the particles carried in the air stream 50 first encounter the liquid stream 106 is identified by the reference number 120 . As can also be seen from FIG., The feed line 94 is designed such that the liquid flow flows over the entire width of the wall 108 or the guide plane 98 .

The guide levels are shown in FIGS. 5 and 6 without curvatures. It is conceivable that the guide levels are curved. Furthermore, it is not essential that the free edges run in a straight line, as shown. It is also conceivable for the mixing section 92 not to be rectangular in cross section, but rather to be round.

FIG. 7 shows a third device 70 according to the invention, in which parts corresponding to device 10 and 90 are identified by corresponding reference numerals. The vacuum generator 36 sucks in air via the suction line 12 via a vacuum housing 74 . The vacuum housing 74 is sealed off from the atmosphere.

Below the end 28 of the suction line 12 , the liquid stream 44 containing the material 11 strikes a collecting container 26 in the form of a cell 80 of a cellular wheel sluice 72 . The particles 11 of the suctioned material 11 surrounded by the liquid collect in the cell 80 . The air flow 58 escaping from the intake line 12 is supplied to the exhaust air 60 via the filter device 34 . The particles 11 present in the blade 80 are fed to the sieve basket 27 via the cellular wheel sluice 72 . Instead of a cellular wheel lock 72 , another known lock can also be used.

After the cell 80 , in which the particles 11 and the liquid 44 are located, has reached a certain filling level, the cellular wheel sluice 72 is rotated about the axis 78 in the direction of the arrow 76 . The particles 11 together with the collected liquid are thus conveyed into the strainer basket 26 without loss of pressure within the vacuum housing 74 . The liquid collection container 32 , in which the liquid 44 collects, is located below the strainer basket 26 . At the bottom of the liquid collection container 32 , a cascade cutter 82 is shown.

The advantage of such a device 70 is that it can be operated continuously. The vacuum generated by the vacuum generator 36 is maintained via the cellular wheel sluice 72 when the respective bucket is emptied. It is therefore not necessary to switch off the device 70 for removing the filtered and collected particles 11 .

In the devices 10 and 70 shown, the first arcuate section 38 is relatively close to the respective collecting container. In order to avoid an undesired reaction of the goods earlier, the liquid flow can also be supplied to the suction line in a region remote from the collecting container. The liquid flow then conveys the material, as shown in FIG. 8, over the corresponding section of the suction line, preferably in a quiet manner, without any significant change in its flow structure.

The suction line shown provides two mixing sections 122 in the form of knee-shaped or curved pipe sections, in which particles 11 carried in the air stream, due to their inertia, immerse themselves in the liquid stream 42 and are carried by the latter. The mixing sections 122 and 124 accordingly correspond to the mixing section 38 as shown in FIG. 2.

All in the description, the following claims and the Features shown can be drawn individually as well also in any combination with each other be essential to the invention.

Claims (27)

1. The invention relates to a method for suctioning off, conveying and / or collecting material resulting from machining processes, in particular combustible, fine-particle, dusty and / or mist-shaped material made of metal, aluminum, magnesium, graphite, fluid, oil or the like. which is sucked in an air stream, brought into contact with a liquid and then collected, characterized in that the liquid is led as a liquid stream ( 44 , 106 ) into a mixing area ( 56 , 57 , 120 ) such that the sucked-in material ( 11 ) is (56 57 120) performed in the mixing region so that it impinges on the liquid flow (44, 106) is immersed in the liquid stream (44, 106) and carried by the liquid stream (44, 106). 2. The method according to claim 1, characterized in that the liquid flow ( 44 , 106 ) with a large volume, in particular at about 4-8 l / min and low speed, in particular at 0.1-0.2 m / s, flows , 3. The method according to claim 1 or 2, characterized in that the speed of the air flow ( 50 ) is approximately 30 to 40 m / s. 4. The method according to claim 1, 2 or 3, characterized in that the liquid stream ( 44 ) containing the material ( 11 ) and the air stream ( 50 ) following the mixing area ( 56 , 57 ) through at least one filter ( 26 , 27 ) is carried out in which the good ( 11 ) is collected. 5. The method according to any one of the preceding claims, characterized in that the liquid ( 44 ) is oil, in particular cooking oil, or water. 6. The device ( 10 , 70 ), in particular for carrying out the method according to one of the preceding claims, with a suction pipe ( 12 ) leading the material ( 11 ) and the air stream ( 50 ), characterized in that the suction pipe ( 12 ) is one Mixing area ( 56 ) having a mixing section ( 38 ) has an inlet ( 40 ) for the liquid flow ( 44 ) into the suction line ( 12 ) in the area of the mixing section ( 38 , 122 , 124 ) or upstream of the mixing section ( 38 , 122 , 124 ) ) is provided and that the mixing section ( 38 , 122 , 124 ) is designed as a first knee or curved tube section ( 38 , 122 , 124 ). 7. The device ( 10 , 70 ) according to claim 6, characterized in that the suction line ( 12 ) and the mixing section ( 38 , 122 , 124 ) have a round cross section. 8. The device ( 10 , 70 ) according to claim 6 or 7, characterized in that the first knee or arch-shaped mixing section ( 38 ) is followed by at least a second knee or arch-shaped mixing section ( 48 , 122 , 124 ). 9. The device ( 10 , 70 ) according to one of claims 6 to 8, characterized in that the first and possibly the second knee or arch-shaped mixing section ( 38 , 48 , 122 , 134 ) has an angle of 90 ° to 120 ° , 10. The device ( 90 , 70 ), in particular for carrying out the method according to one of claims 1 to 5, with a suction pipe ( 12 ) guiding the material ( 11 ) and the air stream ( 50 ), characterized in that the suction pipe ( 12 ) has a mixing section ( 92 ) having the mixing area ( 120 ), that in the area of the mixing section ( 92 ) or upstream of the mixing section ( 92 ) there is an inlet ( 94 ) for the liquid flow ( 106 ) into the suction line ( 12 ), in the mixing section ( 92 ) has at least two guide means ( 98 , 100 , 102 , 104 ) lying one behind the other in the flow direction for guiding the liquid flow ( 106 ) such that the liquid flow ( 106 ) coming from the inlet ( 94 ) via the first guide means ( 98 ) flows and pours onto the second guide means ( 100 ), the air flow ( 50 ) passing between the first and second guide means ( 98 , 100 , 102 , 104 ) can flow. 11. The device ( 90 ) according to claim 10, characterized in that the liquid flow ( 106 ) in the flow direction over the entire width of the mixing section ( 92 ), which is transverse to the longitudinal axis ( 116 ), from one guide means ( 98 ) to another guide means ( 100 ) pours. 12. The device ( 90 ) according to claim 10 or 11, characterized in that the guide means ( 98 , 102 or 100 , 104 ) each extend from one wall ( 108 or 110 ) of the mixing section ( 92 ) in the direction of the opposite wall ( 110 or 108 ) of the mixing section ( 92 ) extend. 13. Device ( 90 ) according to one of claims 10, 11 or 12, characterized in that the guide means ( 108 , 110 , 112 , 114 ) are designed as guide planes and are arranged such that they and the longitudinal axis ( 116 ) of the mixing section ( 92 ) each include an angle of less than 90 °, and in particular an angle in the range from 40 ° to 85 °. 14. The device ( 90 ) according to any one of claims 10 to 13, characterized in that the guide means ( 108 , 110 , 112 , 114 ) overlap each other when viewed in the longitudinal direction ( 116 ) of the mixing section ( 92 ) and / or that the longitudinal direction ( 116 ) preferably runs vertically. 15. The device ( 90 ) according to any one of claims 10 to 14, characterized in that the cross section of the mixing section ( 92 ) is rectangular and that the guide means ( 108 , 110 , 112 , 114 ) are rectangular guide planes. 16. The device ( 10 , 70 ), in particular for carrying out the method according to one of claims 1 to 5, with a suction line ( 12 ) guiding the material ( 11 ) and the air stream ( 50 ), characterized in that the suction line ( 12 ) a mixing section ( 38 ) having the mixing area ( 56 ), that in the area of the mixing section ( 38 , 122 , 124 ) or upstream of the mixing section ( 38 , 122 , 124 ) an inlet ( 40 ) for the liquid flow ( 44 ) into the suction line ( 12 ) is provided and that upstream of the mixing section ( 38 , 122 , 124 ) and preferably also upstream of the inlet ( 40 ) flow guide means ( 52 ) are provided which redirect or deflect the air flow ( 50 ) in such a way that that of the air flow (50) entrained Good (11) collides with the liquid flow (44, 106) into the liquid flow (44, 106) is immersed and carried by the liquid stream (44, 106). 17. The device ( 70 ) according to at least one of claims 6 to 9 and / or at least one of claims 10 to 15 and / or claim 16. 18. Device ( 10 , 70 , 90 ) according to one of claims 6 to 17, characterized in that an expansion ( 53 ) of the suction line is provided downstream of the mixing region ( 56 ) or the mixing section ( 38 , 122 , 124 ). 19. The device ( 10 , 70 , 90 ) according to any one of claims 6 to 18, characterized in that the suction line ( 12 ) upstream of the mixing section ( 38 , 122 , 124 ) extends largely vertically. 20. The device ( 10 , 70 , 90 ) according to one of claims 6 to 19, characterized in that the suction line ( 12 ) downstream of the mixing section ( 48 , 92 ) runs largely vertically. 21. The device ( 10 , 70 , 90 ) according to one of claims 6 to 20, characterized in that downstream of the mixing section or the mixing sections ( 38 , 48 , 92 , 122 , 124 ) a collecting container ( 26 , 27 , 80 ) for the good ( 11 ) is arranged. 22. The device ( 10 , 70 , 90 ) according to claim 21, characterized in that the collecting container ( 26 ) is a sieve basket ( 27 ) through which the liquid stream ( 44 ) containing the material ( 11 ) and the air stream ( 50 ) pass becomes. 23. The device ( 10 , 70 , 90 ) according to one of claims 21 or 22, characterized in that the collecting container is a cell ( 80 ) of a lock ( 72 ) pouring into a sieve basket ( 26 ). 24. The device ( 10 , 70 , 90 ) according to any one of claims 21, 22 or 23, characterized in that the liquid stream ( 44 , 106 ) containing the good ( 11 ) on the good present in the collecting container ( 26 , 80 ) ( 11 ) hits. 25. The device ( 10 , 70 , 90 ) according to at least one of claims 21 to 24, characterized in that the screen basket ( 26 ) is connected to a vacuum source ( 36 ) via a filter device ( 34 ). 26. The device ( 10 , 70 , 90 ) according to at least one of claims 21 to 25, characterized in that a liquid collecting container ( 32 ) is arranged below the strainer basket ( 26 ). 27. The device ( 10 , 70 , 90 ) according to claim 26, characterized in that a pump ( 45 ), in particular a screw pump, is provided which transfers the liquid ( 42 ) in particular from the liquid collecting container ( 32 ) to the feed ( 40 , 94 ) promotes.