This application claims the filing benefit of International Patent Application No. PCT/EP2009/006105, filed Aug. 22, 2009, which claims the filing benefit of German Patent Application No. 10 2008 046 413.9 filed Sep. 4, 2008, the contents of which are incorporated herein by reference.
The invention relates to a device for separating paint overspray from the overspray-laden booth exhaust air from paint shops having
On manual or automatic application of paints onto objects, a sub-stream of the paint, which generally contains both solids and solvent and/or binder, is not applied onto the object. In specialist circles, this sub-stream is known as “overspray”. The overspray is entrained by the air stream in the spray booth and sent for separation.
In particular in installations with relatively high paint consumption, for example in installations for painting vehicle bodies, wet separation systems are preferably used. In commercially known wet separators, water flows together with the booth exhaust air arriving from above to a nozzle which accelerates air flow. In this nozzle, the through-flowing booth exhaust air is swirled with the water. As this happens, the overspray particles largely pass over into the water, such that the air leaves the wet separator in a substantially purified state and the paint overspray particles are located in the water, from which they may then be recovered or disposed of.
In known wet separators, a relatively large amount of energy is required to circulate the very large quantities of water which are necessary. Treating the rinsing water is costly due to the elevated use of paint-binding and detackifying chemicals and disposal of paint sludge. Furthermore, due to intimate contact with the rinsing water, the air absorbs a great deal of moisture which, when the air is recirculated, in turn results in elevated energy consumption for air treatment.
In contrast, in commercially known devices of the above-mentioned type separation is performed by dry methods in that the paint overspray particles entrained by the booth exhaust air are ionised as they flow past the electrode apparatus and, due to the electric field established between the separation surface and the electrode apparatus, migrate to the separation surface, on which they separate out. The paint overspray particles adhering to the separation surface may then for example be mechanically scraped off therefrom and conveyed away.
Such separators have a very effective cleaning action. However, if operation is to be continuous, constant care must be taken to ensure that a sufficiently strong electric field can form between the separation surface and the electrode apparatus, something which is only possible up to a certain layer thickness of paint overspray on the separation surface, since such a layer has an insulating action. The necessary continuous removal of the paint overspray from the separation surface is, however, associated with very considerable structural complexity and may be susceptible to breakdown.
The present invention is directed to resolving these and other matters.
An object of the present invention is accordingly to provide a separation device of the above-mentioned type, in which conveying of paint overspray away from the separation surface is improved and simplified.
This object may be achieved in a device of the above-mentioned type in that
The invention thus combines the advantage of good separation of paint overspray from booth exhaust air by means of an electric field with good transport of paint overspray in a liquid.
Thanks to the separation liquid constantly flowing along the separation surface, paint overspray absorbed thereby is continuously conveyed away, such that adhesion of paint overspray to the separation surface is reduced, which adhesion would result in insulation thereof.
It is favourable for the electrode apparatus to comprise a plate-shaped electrode and at least one wire electrode. A wire electrode acts as a discharge electrode, by means of which the paint overspray particles entrained by the booth exhaust air may be effectively ionised. Thanks to the interplay between a plate-shaped electrode and the separation surface, a homogeneous field can be formed, by means of which the ionised paint overspray particles may be reliably directed to the separation surface.
It is here advantageous for the plate-shaped electrode to take the form of a grid electrode. Swirling occurs at the grid which results in a more uniform distribution of the paint overspray particles in the booth exhaust air flowing past the grid, which in turn has a favourable impact on the separation thereof on the separation surface.
The efficiency of ionisation of the paint overspray particles is increased if the electrode apparatus comprises a plurality of wire electrodes which extend parallel to one another.
It is advantageous for a separation unit to be provided which comprises two separation surfaces oriented in different directions. If the separation surfaces of at least one separation unit extend parallel to one another in at least one portion, a plurality of separation units may be arranged in a cascading series, whereby good use is made of the available structural space.
It is in particular favourable for a plurality of separation units to be arranged such that two separation units in each case having one separation surface are opposite one another and an electrode apparatus is in each case arranged between the opposite separation surfaces of two separation units. As a result, a single electrode apparatus interacts with two separation surfaces, so improving the effectiveness of the device.
If the at least one separation surface comprises at least one curved portion which extends along the at least one wire electrode, it is possible to bring about a reduction in the flow velocity of the booth exhaust air in the region of the wire electrode. A volume of the booth exhaust air accordingly spends longer in the region of influence of the wire electrode, such that a larger proportion of paint overspray particles is ionised in this volume. In addition, swirling and turbulence arises in the region of curvature which makes the distribution of paint overspray particles in the booth exhaust air more uniform.
It is here favourable for the number of curved portions of the at least one separation surface to match the number of wire electrodes, such that the stated effects occur in the region of each wire electrode.
Particularly good separation results may be achieved with a device in which the curvature of one or more curved portions extends in cross-section over a circular arc, the centre point of which is concentric to the wire electrode.
Overall, it is advantageous for effective separation for the at least one wire electrode to be arranged such that the overspray-laden booth exhaust air reaches it before the plate-shaped electrode.
It is to be understood that the aspects and objects of the present invention described above may be combinable and that other advantages and aspects of the present invention will become apparent upon reading the following description of the drawings and detailed description of the invention.
While this invention is susceptible of embodiment in many different forms, there is shown in the drawings and will herein be described in detail one or more embodiments with the understanding that the present disclosure is to be considered as an exemplification of the principles of the invention and is not intended to limit the invention to the embodiments illustrated.
Reference will be made first of all to
The painting booth 2 comprises a painting tunnel 6 arranged on top, which is bounded by vertical side walls 8a, 8b and a horizontal booth ceiling 10, but is open at the end faces and downwards in such a manner that overspray-laden booth exhaust air can flow downwards. The booth ceiling 10 is configured in conventional manner as the lower boundary of the air feed chamber (not shown) with a filter ceiling.
A steel construction 14 is arranged at the level of the lower opening 12 of the painting tunnel 6 flanked by the lower edges of the side walls 8a, 8b, which construction carries a per se known conveying system 16, which is not described in greater detail here. The latter is capable of conveying vehicle bodies 4 to be painted from the input side of the painting tunnel 6 to its output side. In the interior of the painting tunnel 6 are located application devices (not separately shown), by means of which the vehicle bodies 4 may be coated with paint in a manner known per se.
Below the lower opening 12 of the painting tunnel 6, there is a separation chamber 18 open at the top towards the painting tunnel 6, in which chamber paint overspray arising during the painting process is separated.
The separation chamber 18 is bounded by a base plate 20 visible in
In the separation chamber 18 there is arranged a separation device 24 having a plurality of separation units 26 arranged in series in the longitudinal direction of the separation chamber 18, which will be described in greater detail below.
In the region of the separation chamber 18 between the separation device 24 and the painting tunnel 6 are located two air baffle plates 28a, 28b, which, starting from the side walls 22a, 22b of the separation chamber 18, initially converge downwards and, in the end region thereof facing the separation device 24, diverge towards the lateral boundaries of the separation device 24. The air baffle plates 28a, 28b and corresponding air baffle plates (not shown) at the end faces extend from above down to the separation device 24.
The separation units 26 rest on a mounting frame 30, which allows air to flow downwards out of the separation device 24. Below the separation device 24 is located a further air baffle plate 32, which extends along the separation device 24 in the separation chamber 18. The air baffle plate 32 comprises a vertical portion 32a, which faces the left-hand side wall 22a in
Between the vertical portion 32a of the air baffle plate 32 and the left-hand side wall 22a in
An overflow channel 40, which will be described in greater detail below, is provided at the vertex of the curved portion 38 of the separation units 26.
The respective outer faces of the side plates 36a, 36b form separation surfaces 42a or 42b, which will likewise be described again further below.
At their lower edges, the side plates 36a, 36b in each case bear an outlet channel 44a, 44b, which extends parallel to the side plates 36a, 36b of the separation units 26 and is inclined downwards towards a first end face 46, at the front in
As may be seen in
If the separation device 24 is arranged in the separation chamber 18 of the painting booth 2, the drip plates 54a, 54b of each separation unit 26 project over the collecting channel 34.
Two adjacent separation units 26 are arranged, while maintaining mutual spacing, in the separation device 24, Between two adjacent separation units 26 and at the free side plates 36a or 36b of the two outermost separation units 26 within the separation device 24, there extends in each case an electrode apparatus 56, each of which is connected with a high voltage source which is not shown separately in
Each electrode apparatus 56 comprises two straight electrode rails 58a, 58b which extend parallel to one another. In a field portion 60 of the electrode apparatus 56, these hold a grid electrode 62, whose edges 64a, 64b, which extend between the electrode rails 58a, 58b, are perpendicular to the latter. In a corona portion 66 of the electrode apparatus 56, the electrode rails 58a, 58b hold a plurality of corona wires 68 acting as a discharge electrode. The corona wires 68 extend in a plane defined by the electrode rails 58a, 58b parallel to the edges 64a, 64b of the grid electrode 62 and are identically spaced apart from one another.
As may be seen in
When the separation device 24 is in operation, a separation liquid flows on the respective separation surface 42a, 42b of the side plates 36a, 36b of the separation units 26 from the top downwards into the outlet channels 44a, 44b, which separation liquid is suitable for absorbing solid particles from the paint overspray arising during the painting process.
To this end, said separation liquid is supplied to the overflow channel 40 in the curved portion 38 of the separation units 26. The separation liquid passes from there over the curved flanks 70a, 70b, which are adjacent to the overflow channel 40, of the curved portion 38 of the separation unit 26 in each case as a continuous film to the side plates 36a, 36b and flows down over the separation surfaces 42a, 42b thereof, still as a continuous film of separation liquid.
The number of corona wires 68 of the electrode apparatus 56 and their spacing from one another may vary as a function of the separation behaviour of the overspray particles. In the present exemplary embodiment, four corona wires 68 are provided, the uppermost of which is arranged next to the curved portion 38 of the separation unit 26, while the corona wire 68 located therebelow is still located in the region next to the respective side plate 36a or 36b of the separation unit 26.
The separation unit 126 differs from the separation unit 26 inter alia in that the outlet channels 144a, 144b project beyond the end face 146 of the separation unit 126. The projecting portions 172a, 172b correspond to the drip plates 54a, 54b described above, which may therefore be omitted from the separation device 124.
As may be seen in
In the electrode apparatus 156 according to the second exemplary embodiment, a protective bar 180 extends perpendicularly between the electrode rails 158a, 158b above the uppermost corona wire 168, which protective bar reduces the risk of any objects or particles which may fall down from the painting tunnel 6 onto the electrode apparatus 156 from coming into contact with the corona wires 168.
Otherwise, the above statements regarding the separation unit 26, the electrode apparatus 56 and the separation device 24 apply mutatis mutandis to the separation unit 126, the electrode apparatus 156 and the separation device 124.
The basic principle of the devices explained above will now be explained using the separation device 24 according to
When vehicle bodies are painted in the painting tunnel 6, the booth air located therein becomes laden with paint overspray particles. These may be still liquid and/or tacky but also already more or less solid. The booth exhaust air laden with paint overspray flows through the lower opening 12 of the painting tunnel 6 into the separation chamber 18. Here, said air is guided by the air baffle plates 28a, 28b towards the separation device 24 and flows between adjacent separation units 26 towards the lower air baffle plate 32.
Corona discharges occur in a manner known per se at the corona wires 68, and such discharges effectively ionise the overspray particles in the booth exhaust air as it flows past.
The ionised overspray particle pass by the side plates 36a, 36b, which are at earth potential, of two adjacent separation units 26 and the grid electrode 62 extending therebetween in the first portion 60 of the electrode apparatus 56. Due to the electrical field formed between the grid electrode 62 and side plates 32a, 32b, the ionised overspray particles separate out onto separation surfaces 42a, 42b of the side plates 36a, 36b of the separation units 26, where they are absorbed by the separation liquid flowing thereover.
Some of the ionised overspray particles separate out onto the separation units 26 as early as in the second portion 66 of the electrode apparatus 56 in the region of the corona wires 68. However, the electrical field present between the corona wires 68 and the respective side plate 36a, 36b of the separation unit 26 is more non-homogeneous than the electrical field in the region of the grid electrode 62, for which reason more directed and more effective separation of the ionised overspray particles occurs here on the corresponding separation unit 26.
The air purified on passing between the separation units 26 is guided by the lower air baffle plate 32 towards the side wall 22b, shown on the right-hand side in
The separation liquid flowing down over the separation units 26 which is now laden with the overspray particles passes at the bottom into the outlet channels 44a, 44b of the separation units 26. Due to the inclination of the outlet channels 44a, 44b, the laden separation liquid flows towards the openings 52a, 52b in the respective end walls 50a, through the latter and thence via the drip plates 54a, 54b into the collecting channel 34. The separation liquid laden with overspray particles flows via the collecting channel 34 out of the painting booth 2 and may be sent for purification and reprocessing, in which the overspray particles are removed from the separation liquid, or for disposal.
In the separation unit 226, the side plates 236a, 236b have corrugated portions 282a, 282b, which adjoin the respective flanks 270a, 270b of the curved portion 238 of the separation unit 226. Between the outlet channels 244a, 244b and the corrugated portions 282a, 282b, the respective side plate 236a, 236b comprises a planar portion 284a, 284b.
Each corrugated portion 282a, 282b has, in each case relative to the central plane, which extends between and parallel to the planar portions 284a, 284b, of the separation unit 226, inwardly curved portions 286a, 286b, 286c, 286d as well as outwardly curved portions 288, which in each case extend along a corona wire 268. The number of inwardly curved portions 286 of each corrugated portion 282a, 282b of the side plates 236a, 236b thus corresponds to the number of corona wires 268 of the electrode apparatus 256.
For clarity's sake, in each case only one of the inwardly curved portions 286a, 286b, 286c and 286d and only one of the outwardly curved portions 288 is provided with a reference numeral.
The curvature of the two lower and of the uppermost inwardly curved portions 286a, 286b and 286d follows a circular arc when viewed in cross-section. The inwardly curved portions 286a, 286b and 286d are in each case arranged relative to an adjacent corona wire 268 such that the latter is concentric in cross-section to the circular arc defining by the profile of the respective curved portion 286a, 286b or 286d. The uppermost inwardly curved region 86d is somewhat shorter in the vertical direction than the lower two inwardly curved regions 286a and 286b.
In the inwardly curved portion 286c arranged below the uppermost curved portion 286d, the radius of curvature declines from the bottom upwards, such that, when viewed in cross-section, the inwardly curved portion 286c has a parabola-like profile. As a result, the spacing between the outside ends of opposite flanks 270a, 270b of two adjacent separation units 226 is smaller in a horizontal plane than the spacing between their opposite planar portions 284a, 284b of the respective side plates 236a, 236b.
The spacing of two adjacent separation units 226 with electrode apparatus 256 arranged therebetween is adjusted such that the corona wires 268, when viewed in cross-section, are in each case concentric to the centre point of the approximately cross-sectionally circular arc-shaped segments defined by two opposite, inwardly curved portions 286a, 286b or 286d.
Due to the inwardly curved portions 286 of the corrugated portions 282a, 282b of the separation units 226, the channel formed there between the separation units 226, through which channel the overspray-laden booth exhaust air flows, is in each case locally widened at that point. As a result, at the level of the inwardly curved regions 286 of the side plates 236a, 236b, there is in each case a reduction in flow velocity, whereby the booth exhaust air flowing past the respective corona wire 268 remains for longer in its region of influence. As result, a greater proportion of overspray in a given volume of booth exhaust air is in turn ionised by the corona wire 268 in question. Thanks to the inwardly curved portions 286, which are arranged in series in the direction of flow of the booth exhaust air, of the side plates 236a, 236b of the separation units 226, a significantly larger proportion of overspray is ionised in the second electrode portion 266 with the corona wires 268 than would be the case with continuously planar side plates 236a, 236b at an identical flow velocity of the booth exhaust air. For this reason it is possible to achieve an overall increase in the throughput of booth exhaust air, since the flow velocity of the overspray-laden booth exhaust air may be raised in such a manner that its residence time in the region of the corona wires 268 corresponds to the residence time at a lower flow velocity and with completely planar side plates 236a, 236b.
Flow velocity may, for example, be increased by a factor of 4 to 6. If, for example, in a separation apparatus 24 with separation units 26 according to the first exemplary embodiment, a flow velocity of the booth exhaust air laden with overspray particles of 0.25 m/s is possible while satisfactory separation performance is still achievable, then if the separation units 226 are used, the flow velocity of the booth exhaust air may be raised to 1 m/s to 1.5 m/s while nevertheless achieving adequate separation results. If the flow velocity is to be increased, the height of the separation apparatuses may be correspondingly increased to achieve the same separation action.
In addition, swirling and turbulence occurs in the region of the corrugated portions 232a, 232b of opposite side plates 236a, 236b of two adjacent separation units 226, whereby the paint overspray particles entrained by the booth exhaust air are uniformly distributed in the region of the corona wires 268 and may thus be more effectively ionised.
In a modification of the electrode apparatuses 56 or 156, which is not shown here in either case, a plate electrode is provided instead of the grid electrode 62 or 162. However, separation of ionised paint overspray particles from the booth exhaust air proceeds more effectively in the presence of the grid electrode 62 or 162, since slight swirling of the booth exhaust air is produced on the grid or grid rods thereof and the ionised paint overspray particles are consequently more homogeneously distributed in the region of the grid electrode 62 or 162 than is the case with a plate electrode with a continuous electrode surface.
In order to reduce any adhesion to the separation surfaces 242a, 242b which may still occur of separated paint overspray particles which have been absorbed by the separation liquid on the separation surfaces 242a, 242b of the separation units 226, the separation surfaces 242a, 242b of each separation unit 226 may be coated with a non-stick coating, such as for example Teflon.
Instead of the overflow channel, from which separation liquid passes over the outer edges thereof and over the curved flanks 70a, 70b, 170a, 170b or 270a, 270b of the curved portion 38, 138 or 238 of the separation units 26, 126 or 226 to the side plates 36a, 36b, 136a, 136b or 236a, 236b, it is also possible to provide separation units 26, 126, 226 with an alternative apparatus with which separation liquid may be applied onto the separation units 26, 126, 226. For example, a sprinkler apparatus, a slot nozzle or simply a tube with orifices may be arranged for this purpose above the curved portion 38, 138 or 238.
It is important for the purposes of interplay with the electrode apparatus 56, 156, 256 and the side plates 36a, 36b, 136a, 136b, 236a, 236b at earth potential of the separation units 26, 126, 226 that the separation liquid be electrically conductive. The separation liquid may be based, for example, on water or on an oil and be provided with additives which assist clumping and/or curing and/or detackifying of paint overspray particles in the separation liquid.
The conductivity of the separation liquid is preferably in the range from 50 to 5000 μS/cm, in particular from 1000 to 3000 μS/cm, and may be adjusted by means of additives, such as for example salts.
Thanks to the above described combination of electrical separation of paint overspray from booth exhaust air laden therewith with the use of the separation liquid for absorbing and conveying away the paint overspray particles, it is possible to achieve efficient and effective purification of overspray-laden booth exhaust air. The purified booth exhaust air may then be resupplied in a circuit to the spray booth as has already been explained above.
It is to be understood that additional embodiments of the present invention described herein may be contemplated by one of ordinary skill in the art and that the scope of the present invention is not limited to the embodiments disclosed. While specific embodiments of the present invention have been illustrated and described, numerous modifications come to mind without significantly departing from the spirit of the invention, and the scope of protection is only limited by the scope of the accompanying claims.
Number | Date | Country | Kind |
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10 2008 046 413 | Sep 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/006105 | 8/22/2009 | WO | 00 | 2/25/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/025844 | 3/11/2010 | WO | A |
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Number | Date | Country | |
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20110154988 A1 | Jun 2011 | US |