SE512482C2 - A filtering device - Google Patents

Abstract

The present invention relates to a filter device comprising a filter cabinet (2), at least one filter chamber (3) provided in the filter cabinet (2) and filter elements (11) provided in the filter chamber (3), wherein a pre-separator (31) is provided to separate coarse particles (32) from the air stream (17) loaded or mixed up with particles before said air stream (17) is fed to filter elements (11) in a filter chamber (3). The pre-separator (31) includes at least one nozzle (39) provided in the filter cabinet (2) and divided into several smaller nozzles (43) and said smaller nozzles (43) extend in parallel with each other.

Description

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OO BJ Filter devices of the above-mentioned type but without pre-separators are known from the document DE 1 407 944. However, it is also previously known to provide filter devices of this type with pre-separators for separating coarse particles before the air flow reaches the filter elements. Such known pre-separators often have a limited ability to separate coarse particles.

The object of the present invention is primarily to further develop known pre-separators in order to e.g. increase their ability to separate. According to the invention, these problems have been remedied in that the filter device mentioned in the introduction has the features which essentially appear from the following claim 1.

Because the filter device has pre-separators with at least one nozzle with said characteristics, a less turbulent air flow is achieved and thus an improved ability to separate coarse particles.

The invention will be explained in more detail below with reference to the accompanying drawings, in which Figure 1 shows a filter device according to the invention in Section; figure 2 shows parts of the filter device according to figure 1 with a perspective view; and figure 3 shows an alternative embodiment of the filter device according to the invention in perspective.

The filter device shown in Figure 1 is intended to separate both coarse and fine particles from particulate-laden air streams, for example such particulate-laden air streams which arise in connection with various processing methods, e.g. in the form of welding fumes during welding or grinding dust during grinding. The filter device has at least one unit 1, which consists of a filter cabinet 2, at least one filter chamber 3 arranged in the filter cabinet 2 which is connected to an air intake pipe 4 and an air outlet pipe 5. The filter chamber 3 is limited at the rear by a rear wall 6 , on the sides of two opposite side walls 7 of the filter cabinet 2 and at the front of a front wall 8. In addition, the filter chamber 3 is delimited at the top by the top side 9 of the filter cabinet and it has an opening 10 at the bottom. Between the rear and front walls 6, 8 a plurality of horizontally arranged filter elements 11. These are tubular in a known manner and they have in a known manner inner support grilles 12 and an outer pleated filter material 13, the folds 14 of which extend in the longitudinal direction of the filter elements 11 between the rear and front walls 6, 8. The filter elements 11 are tightly connected to the rear wall 6 and they have front openings 15 which connect tightly to the front wall 8 around openings 16 therein.

These filter elements 11 function in such a way that particle-laden air streams 17 are caused to flow into the filter elements 11 so that the particles in them stick to the outside of the filter material 13. The thus particle-free, clean air 18 is caused to flow out of the filter elements 11 via its front openings 15 and via the openings 8 of the front wall 8 to a clean air chamber 19 and via this out of the filter cabinet 2 via the air outlet pipe 5. The clean air chamber 19 is arranged at the front of the filter cabinet 2 and it is preferably closed by an openable door 20 which in the closed position forms or enters the front of the filter cabinet 2. A filter cleaning device 21 is arranged on the door 20 or in another suitable manner in the clean air chamber 19. This has a compressed air device 22 and a device connected thereto for directing compressed air shocks into the filter elements 11. The latter device in this case has solenoid valves 23 and these connected cleaning pipes 24.

The cleaning pipes 24 extend vertically in front of the front wall 8 of the filter chamber 512 482 3 and each cleaning pipe 24 is associated with a filter element 11 and has air discharge openings, preferably in the form of slots (not shown) via which compressed air shocks are directed into the filter elements 11 via the openings 16 and 15 so that the filter material 13 of the filter elements 11 is momentarily expanded, whereby particles adhered to its outside are shaken off and caused to fall down and out via the opening 10. The filter material 13 is momentarily expanded by the same folding outwards in the folds 14 at the compressed air shock, while the same folds inwards in the fold 14 after the compressed air shock.

The above-mentioned cleaning process is controlled by opening the solenoid valves 23 during and at certain times, which can take place during and / or after the operation of the filter device.

The compressed air device 22 may have a tube in which compressed air is stored and this tube may be attached to the top of the inside of the door 20. At the bottom on the inside of the door 20 may be arranged holders 26 at which flattened end portions 27 of the cleaning pipes 24 are arranged by means of fastening screws 28 which may be threaded through holes 29 in said end portions 27.

At the rear of the filter cabinet 2 itself, in the embodiment shown, a pre-separator 31 is arranged in which coarse particles 32 are separated from the particle-laden air stream 17 before it reaches the filter elements 11 in the filter chamber 3.

This pre-separator 31 is a dynamic dust separator in which the particle-laden air stream 17 is preferably imparted at a high speed and deflected so that the coarse particles 32 are precipitated by mass forces arising during deflection.

The rear wall 6 of the filter chamber 3 may form a front wall of the pre-separator 31, a rear wall 33 of the filter cabinet 2 may form a rear wall of the pre-separator 31 and the opposite side walls 7 of the filter cabinet 2 may form opposite side walls of the pre-separator 31.

The pre-separator 31 has an air guide means 34 which can connect to the rear wall 33 of the filter cabinet 2 so that an air inflow part 35 is formed between it and the rear wall 33. The air control means 34 also forms in the upper parts of the pre-separator 31 an air flow part 36 and below air inflow and the air flow parts 35, 36 are arranged a separation space 37 in which coarse particles 32 are separated from the air flow 17.

The particulate air stream 17 entering through the air intake pipe 4 is caused to flow downwardly through the air inflow portion 35 and out of it in a downward direction via a downwardly directed nozzle 39 formed by the air guide means 34, preferably together with the rear wall 33. In that the air guide means 34 has a direction obliquely downwards towards the rear wall 33 part 38, which is located upstream of the nozzle 39, the flow area of the air inflow part 35 decreases in the downward direction, which means that the flow rate of the particle-laden air stream 17 increases as it flows downwards out of the nozzle 39. into the separation space 37. This is designed to divert the air flow 17 in an area 40 below the nozzle 39 in the direction upwards into the air flow part 36 so that said separation of the coarse particles 32 takes place within said area 40.

The air stream 17 freed from coarse particles 32 but still containing particles is caused to flow through the air flow portion 36 and from there through a flow opening 41 in the rear wall 6 into the filter chamber 3. In this the particle-laden air stream 17 is brought in the manner flow into the filter elements 11 on the outside of which smaller particles deposit. The nozzle 39 preferably has one or more, for example four, air guide members 42, for example air guide plates, which extend parallel to the particle-laden air stream 17 flowing through the nozzle 39. These air guide members 42 divide the nozzle 39 into a number of, e.g. five smaller nozzles 43 for the air flow 17 so that below the nozzle 39 a less turbulent air flow is obtained in and / or after the nozzle 39. Said smaller nozzles 43 extend parallel to each other and they preferably have a greater length than width.

In order to achieve a particularly advantageous separating effect in the separating space 37, the nozzle 39 can have a definite width or diameter C. Furthermore, in the separating space 37 an air guide screen 44 can be arranged, which can be arranged on the rear wall 6 and extend in direction baked from this. The air guide screen 44 is preferably arranged so that its rear edge 45 is at such a level below the nozzle 39 which is at a distance D therefrom. In addition, an air gap 46 is preferably formed with the width E between the rear edge 45 of the air guide screen 44 and the front parts of the nozzle 39. By arranging the width C, the distance D and the width E with a certain aspect ratio to each other and to the speed of it from the nozzle 39 outflowing particulate air stream 17, said advantageous separation effect can be obtained.

The air guide means 34 can be arranged on a lid 47 which forms or is included in the upper side 9 of the filter cabinet 2 so that the air guide means 34 follows up when the lid 47 is removed. As a result, the inner parts of the pre-separator 31 can be easily released by removing the cover 47.

Figure 3 shows an embodiment of the filter device where at least two units 1 having filter chambers 3 arranged on each other are arranged on each other. In this embodiment, the pre-separator 31 can be common to the bath units 1 or more units 1. If the pre-separator 31 is contained in the filter cabinet 2, parts can be arranged behind each filter chamber 3. 31a of the pre-separator 31 and when the units 1 are placed on top of each other, said parts 31a together form a pre-separator 31 common to the two units 1. In this the air inflow part 35 can be none in the upper unit 1 and there can be a flow opening 41 to the filter chamber 3 only in the upper unit 1 or possibly in each unit 1.

The object of the invention is not limited to the embodiments described above and shown in the drawings. As not described alternatives it can be mentioned that the term air currents may include air-mixed gases of a type other than welding fumes, grinding dust or the like which need to be particle filtered, the pre-separator 31 may be arranged outside the filter cabinet 2, the air control means 34 may be a completely circular tube for example is immersed between the walls 6 and 33, the air guide screen 44 can be of a different design than shown, more than two units 1 can be placed on top of each other which together form a common pre-separator 31, the nozzles 43 can be formed by air guide parts other than air guide plates 42 and the nozzle 39 need not be located above the separation space 37, but it may have a different suitable orientation in relation thereto.

UIIHIH 11

Claims (18)

512 482 9 Patent claims: II II II II II II II II II II II Filter device having a filter cabinet (2), at least one filter chamber (3) arranged in the filter cabinet (2) and filter elements (11) arranged in the filter chamber (3), the particle-laden air stream (17) being led into the filter chamber (3) and into the filter elements (II) so that particles present in the air stream (17) adhere to the outside of the filter elements (II) while purified air (18) of the filter elements (II) is led out of these, a filter cleaning device (21) having a compressed air device (22) and a device for directing compressed air shocks into the filter elements (II) to cause them to expand momentarily and thereby shake off the same attached particles, a pre-separator (31) being arranged to separate coarse particles ( 32) from the particle-laden air stream (17) before it is led to the filter elements (II) in the filter chamber (3), and (fl ... s \ QI \ J wherein the pre-separator (31) has at least one nozzle (39) which is arranged to direct it to pre-ski particle-laden particulate air stream (17) into a separation space (37) in which the air stream (17) is deflected in such a direction that the coarse particles (32) precipitate out of the air stream (17) by mass forces arising during the deflection. , characterized in that the pre-separator (31) has at least one nozzle (39) which is divided into several smaller nozzles (43), and that said smaller nozzles (43) extend parallel to each other. Filter device according to claim 1, characterized in that said smaller nozzles (43) are formed by arranging in the nozzle (39) one or more air control parts (42) which are arranged parallel to each other. Filter device according to Claim 1 or 2, characterized in that an air guide screen (44) is arranged in the separation space (37) and that an air gap (46) is formed between the air guide screen (44) and the nozzle (39). Filter device according to claim 3, characterized in that the air gap (46) between the air guide screen (44) and the nozzle (39) has a certain width (E) and that the width or diameter (C) of the nozzle (39), a distance (D) between the nozzle (39) and the air guide screen (44), the width (E) of the air gap (46) and the velocity of the particulate air stream (17) flowing from the nozzle (39) are in a certain ratio to each other. Filter device according to claim 4, characterized in that said air gap (46) is formed between an outer edge (45) of the air guide screen (44) and outer parts of the nozzle (39). Filter device according to one of the preceding claims, characterized in that the nozzle (39) is arranged to increase the speed of the inflowing particle-laden air stream (17). Filter device according to claim 6, characterized in that the nozzle (39) has a smaller flow area than an air inflow part (35) arranged in the flow direction of the particle-laden air stream (17), so that the speed of the nozzle (39) the particle-laden air flow (17) increases in the nozzle (39). Filter device according to one of the preceding claims, characterized in that the nozzle (39) is arranged above the separation space (37) and in that the nozzle (39) directs the inflowing particle-laden air stream (17) downwards into the separation space (37). Filter device according to claim 8, characterized in that the pre-separator (31) above the separation space (37) has an air inflow part (35) via which an air stream (17) flows to the nozzle (39) and that the pre-separator (31) above the separation space (37) also has an air flow part (36) arranged next to the air inflow part (35) via which an air flow (17) flows from the separation space (37) to the filter chamber (3). A filter device according to any one of the preceding claims, wherein the filter cabinet (2) has at least two 512 4-82 l / superimposed units (1), each unit (1) having a filter chamber (3), characterized in that the pre-separator (31) is common to said two or more units (1). 11. ll. Filter device according to one of the preceding patent claims, characterized in that the nozzle (39) and the separation space (37) are arranged in the filter cabinet (2). Filter device according to claim 11, characterized in that a rear wall (6) of the filter chamber (3) forms a front wall of the separation space (37) and of an air flow part (36) between the separation space (37) and the filter chamber (3) and that a rear wall (33) of the filter cabinet (2) arranged behind the rear wall (6) of the filter chamber (3) forms a rear wall for the separation space (37) and for an air inflow part (37) arranged above the separation space (37). ). Filter device according to claim 11 or 12, characterized in that an air control means (34) included in the pre-separator (31) which is arranged to control the particle-laden air stream (17) flowing into the pre-separator (31) to the nozzle (39) forms a air inflow part (35) in the pre-separator (31) and / or the nozzle (39) together with a rear wall (33) of the filter cabinet (2). Filter device according to one of Claims 11 to 13, characterized in that the filter elements (11) are tightly connected to a rear wall (6) of the filter chamber (3) behind which the rear wall (6) of the pre-separator (31) is arranged. that the filter elements (II) extend from said rear wall (6) in a horizontal direction to a front wall (8) of the filter chamber (3), that the filter elements (III) have front openings (15) and connect 512 482 IQ close to the front wall (8) around openings (16) therein, that the front openings (15) of the filter elements (11) via the openings (16) of the front wall (8) communicate with a clean air chamber (19) via which clean air (18) can flow out of the filter cabinet (2) and that the cleaning pipes (24) included in the filter cleaning device (21) are arranged vertically in front of the openings (16) of the front wall (8) and have air discharge openings for directing compressed air shocks into the filter elements. (11) to cause these to expand momentarily. Filter device according to claim 14, characterized in that the cleaning pipes (24) are arranged on an openable door (20) of the filter cabinet (2), which door (20) in the closed state forms a front wall of the filter cabinet (2). Filter device according to any one of claims 11-15, characterized in that a wall (6) of the filter chamber (3) at the top has a flow opening (41) through which an air stream (17) passes from the pre-separator (31) to the filter chamber (3). Filter device according to one of Claims 11 to 16, characterized in that the pre-separator (31) extends along several units (1) provided with filter chambers (3) so that it becomes common to the units (1). Filter device according to claim 17, characterized in that the pre-separator (31) common to the units (1) has an air inflow part (35) in the uppermost of said units (1), that the common pre-separator (31 ) has an opening in the bottom of said units (1) for discharging coarse particles (32) from the common pre-separator (31) and that at least one flow opening (41) 512 4-82 / 3 is arranged between the common pre-separator ( 31) and a filter chamber (3) in the upper of the units (1).