The present invention relates to a device for stirring and aerating a liquid in a treatment vessel.
International application WO 98 30319 discloses a device for stirring and aerating a liquid in a treatment vessel, comprising:
In the above prior art device, the means for incorporation of air comprise a pipe discharging into the duct under the funnel and means for directing compressed air into said pipe.
Although they encourage the process of aeration of the liquid, in particular with a view to biodegrading it, the above air injection means consume a large amount of energy, which burdens the overall energy balance of the device.
This is a particular problem when it is a question of treating large volumes of liquids heavily charged with organic materials, when the quantity of energy to be expended to inject sufficient air to degrade the liquid may prove prohibitive.
An object of the present invention is to provide economic means that can either be substituted for the air injection means, in particular for standard volumes of normally charged liquids, or added to said injection means, in particular for large volumes of heavily charged liquids.
The above object of the invention is achieved by a device for stirring and aerating a liquid in a treatment vessel, including:
characterized in that said air incorporation means comprise, in addition to the upper edge of said funnel, peripheral means disposed in the vicinity of said edge and adapted to incorporate air at atmospheric pressure into said liquid entirely because of the effect of the movement of said liquid.
Thanks to the above features, the movement of the liquid in the vicinity of the upper edge of the funnel is exploited to incorporate air therein, so that said incorporation is achieved by passive means, i.e. without it being necessary to use an additional source of energy.
By substituting the above fixed air incorporation means for the air injection means, or adding them thereto, depending on the volume of liquid to be treated and/or the organic material charge of said liquid, the overall energy balance of the stirring and aeration device can be significantly improved compared to the prior art.
According to other features of the device according to the invention:
The present invention also consists in a liquid treatment vessel equipped with a device according to any one of the preceding claims [sic].
Other features and advantages of the present invention will become apparent in the light of the following description and from an examination of the appended drawings, in which:
bis is a diagrammatic view in section of a liquid treatment vessel equipped with a second embodiment of the device according to the invention,
In the above figures, identical reference numbers designate identical or analogous parts or sets of parts.
The treatment vessel 1 can be covered with insulation 4 on its external face and include a device 10 in accordance with the invention for stirring and aerating the liquid.
The device 10 is disposed inside the vessel 1 and comprises a funnel 11 that widens in the upward direction, and is placed in the upper portion of the vessel 1, and whose upper edge forms with the wall of the vessel 1 a free space 11a for the passage of the liquid 3.
The device further includes a duct 12 connected to the funnel and extending in the direction of the bottom of the vessel 1, the duct having an opening 12a at the top communicating with the bottom of the funnel 11 and an opening 12b at the bottom discharging in the vicinity of the bottom of the vessel 1.
The device 10 is further provided with means for aspirating the liquid into the interior of the duct 12, comprising a main screw 13 disposed under the bottom of the funnel 11 and fixed to a vertical shaft 14 adapted to be driven in rotation by a gear motor 15.
The screw 13 is preferably of a type known in the art with mainly axial flow, i.e. of the type adapted to generate a field of velocities only slightly inclined to the axis of the screw.
This type of screw is used in particular in applications in which it is essential, for reasons of safety, to enclose the screw: because this type of screw generates a mainly axial flow, it limits the losses of energy at the enclosing walls, and thus optimizes efficiency.
This type of screw is found in tugs, for example, where it is essential to protect the screw to prevent it becoming entangled in the cables of ships to be towed.
An anti-vortex member 16 is preferably disposed inside the sleeve 12 below the screw 13 to prevent rotation of the liquid 3 in the duct 12.
As shown in
The device according to the invention comprises means disposed in the vicinity of the upper edge of the funnel 11 and adapted to incorporate air at atmospheric pressure into the liquid 3 due only to the effect of the movement of the liquid.
As shown in
As shown in
This member can take the form of an annular trough, for example, as shown here, or an annular metal grid.
An optional pipe P (shown in
The device 10 can be connected to the interior of the vessel 1 by lugs 19a with passages for the liquid 3 between them.
Refer now to
Only those features that distinguish it from the previous embodiment are described hereinafter.
The duct 12 extends higher than the upper edge of the funnel 11 and its upper end is closed by a plate 20 supporting the gear motor 15.
The duct 12 includes a first series of windows 21 uniformly distributed around its perimeter and situated at the level of the liquid 3 inside the funnel 11.
The duct 12 further includes a second series of windows 22 uniformly distributed around the perimeter of the duct 12 and situated higher than the bottom of the funnel 11.
The device 10 is provided with means for adjusting the flowrate of the liquid 3 and foam 23 aspirated by the main screw 13 into the interior of the duct 12 via the windows 21 and 22.
The aforementioned adjustment means comprise, firstly, a first sleeve 25 disposed around the duct 12 at the level of the first series of windows 21 and, secondly, a second sleeve 26 disposed around said duct 12 at the level of the second series of windows 22.
The position of each of the sleeves 25 and 26 relative to the respective windows 21 and 22 can be adjusted vertically by appropriate clamping means, not shown.
In this second embodiment, the device 10 also comprises means for regulating the level of the liquid 3 in the funnel 11.
Those means can comprise an overflow pipe 27 disposed inside the funnel 11 and whose position can be adjusted vertically.
In this second embodiment, the device 10 also comprises static means 30 disposed inside the duct 12 and below the anti-vortex member 16 for stirring the liquid 3 by creating turbulence.
As shown in
The tube 31 is fixed to the bottom of the vessel 1 by appropriate means.
The obstacles 32 and the internal wall of the duct 12 form passages for the circulation of the liquid.
As shown in
For example, the upper portion of the tube 31, below the anti-vortex member 16, includes two superposed obstacles 32 and the lower portion of the duct 12 also includes two superposed obstacles 32.
In a variant that is not shown, the obstacles 32 can be readily distributed over all of the portion of the tube 31 disposed in the duct 12.
As shown in
In a variant that is not shown, the obstacles 32 can take the form of disks.
In another variant that is not shown, the static stirring means for creating turbulence can take the form of obstacles disposed on the internal wall of the duct 12 and forming an axial passage for the flow of the liquid 3.
The obstacles can readily be distributed over the whole of the portion of the duct 12 situated below the anti-vortex member 16 or grouped together, firstly, below the anti-vortex member 16 and, secondly, in the lower portion of the duct 12.
In this case also, the obstacles can take the form of disks or cups whose concave side is directed toward the bottom of the vessel 1.
In the second embodiment, the device 10 does not include any annular member 18 (see
However, it must be understood that the invention also includes a device having the above kind of annular member in addition to the features of the second embodiment.
More generally, it must be understood that the invention includes any device combining some or all of the features of the first and second embodiments described hereinabove, provided that the device comprises peripheral air incorporation means in the vicinity of the upper edge of the funnel 11.
Thus the invention also includes a device comprising windows 21, 22 but no static stirring means 30 for creating turbulence, for example.
The invention also includes a device having dynamic means for stirring the liquid situated in the duct, conforming for example to the teaching of patent application EP 0 687 497.
The dynamic stirring means can comprise a “long shaft”, i.e. a shaft extending under the main screw 13 inside the duct 12 and provided with means for stirring the liquid situated inside the duct 12.
The device that has just been described operates in the following manner.
The liquid 3 to be treated is discharged into the vessel 1 via the orifice 2 up to a level situated above the upper edge of the funnel 11 (see
The liquid 3 is also discharged into the interior of the funnel 11.
The gear motor 15 drives rotation of the shaft 14 which in turn drives rotation of the main screw 13.
The rotation of the main screw 13 causes aspiration of the liquid 3 into the duct 12 with the result that the liquid 3 flows continuously downward in the duct 12, enters the space 33 between the lower end of the duct 12 and the bottom of the vessel 1, flows upward between the duct 12 and the internal wall of the vessel 1, and so on.
The anti-vortex member 16 prevents rotation of the liquid in the duct 12 below the screw 13.
Because of the suction caused by the screw 13, the level of the liquid 3 inside the funnel 11 is below the level of the liquid inside the vessel 1.
This results in the liquid 3 cascading over the whole of the periphery of the funnel 11.
The presence of the peripheral air incorporation means, such as the projections 17 and/or the annular member 18, completes the incorporation of air caused only by the presence of the upper edge of the funnel 11, which causes the liquid 3 to drop into the funnel 11.
The projections 17 form obstacles separating the flow of the liquid 3 into a plurality of streams which naturally trap air on joining together again.
The annular member 18 forms an obstacle for creating additional cascades contributing to the incorporation of air.
In the second embodiment (see
It will be noted that the overflow pipe 27 adjusts the level of the liquid 3 inside the funnel 11 so that it is substantially halfway up the windows 21.
It will also be noted that the windows 21 ensure that the foam 23 on the surface of the liquid 3 is drawn into the duct 12, thereby preventing the foam from flying off and polluting the environment.
It will further be noted that the flowrate of the liquid 3 can be adjusted by moving the sleeves 25 and 26 relative to the windows 21 and 22.
When the liquid 3 flows into the duct 12, turbulence is created below each of the obstacles 32, dividing the bubbles of air 34 into microbubbles, which encourages the biodegradation process, and thus improves the efficiency of the device according to the invention.
In each of the embodiments described hereinabove, the gas bubbles between the internal wall of the vessel 1 and the duct 12 accelerate upward movement of the liquid, encouraging the circulation of the liquid inside the vessel 1, which improves efficiency.
Accordingly, the liquid to be treated passes through the duct 12 several times and therefore receives several oxygenation treatments.
On each passage, because of the projections 17 and/or the annular member 18, air at atmospheric pressure is incorporated into the liquid 3 exclusively by the effect of the movement of the liquid, this air accounting for the biodegradation of the liquid 3.
The optional use of a main screw 20 of the type described hereinabove, i.e. for which most of the flow is axial, increases the height the liquid 3 falls at the upper edge of the funnel 11, and thus encourages the action of the projections 17 and/or the annular member 18 and improves the efficiency of the device.
It goes without saying that combining the projections 17 with the annular member 18 improves the efficiency of the device.
Of course, the optional injection of compressed air into the interior of the duct 12 also increases the efficiency of the device.
The rotation speed of the main screw 20 is chosen to match the operating conditions of the device according to the invention to the nature of the liquid to be treated.
As is now clear, the movement of the liquid 3 in the vicinity of the upper edge of the funnel 11 is exploited to incorporate additional air therein by passive means, i.e. without it being necessary to use an additional source of energy.
By substituting the air incorporation means 17, 18 for the air injection means, or by adding them to the latter, depending on the volume of liquid to be treated and/or the organic materials charge of that liquid, the overall energy balance of the stirring and aeration device can be significantly improved compared to the prior art.
Other embodiments comprising mobile means for adding to the effect of incorporation of air obtained by using the peripheral means 17, 18 are briefly described next.
In the third embodiment, shown in
This second anti-vortex member 40 takes the form of at least two vertical plates 40a each extended upward by a reinforcing rib 41 extending as far as the upper end of said duct 12.
The second anti-vortex member 40 preferably takes the form of four vertical plates 40a uniformly distributed inside the duct 12 and each extended upward by a reinforcing rib 41.
The second anti-vortex member 40 creates a friction force on the liquid 3 which causes agitation to facilitate the incorporation of air into the liquid 3.
In a variant shown in
This liquid accelerator takes the form of a secondary screw 45 disposed above the second anti-vortex member 40 and constrained to rotate with the shaft 14.
The pitch of the secondary screw 45 is the same as the pitch of the main screw 13.
Moreover, the liquid accelerator further comprises an anti-vortex member 46 disposed above the secondary screw 45 and inside a cylindrical chimney 47.
The chimney 47 is fixed to the internal edge of the reinforcing ribs 41 to form passages 48 for the liquid between the reinforcing ribs 41 and in conjunction with the duct 12.
The secondary screw 45, the anti-vortex member 46, and the chimney 47 are situated between the two series of windows 21 and 22 which, in this variant, are provided with adjustment sleeves 25, 26.
The rotation of the main screw 13 aspirates the liquid 3 into the duct 12 via the windows 21 and 22 and the liquid 3 therefore flows continuously downward in the duct 12.
Moreover, the rotation of the secondary screw 45 accelerates the aspiration of the liquid 3 into the duct 12 via the windows 21 and 22 and some of the liquid rises up again through the passages 48 between the duct 12 and the chimney 47, which further accentuates this phenomenon of acceleration of the liquid inside said duct 12.
The anti-vortex member 46 prevents rotation of the liquid in the chimney 47.
The acceleration and the aspiration of the liquid have the effect of subjecting it to violent agitation, encouraging the incorporation of air into the liquid.
This variant is suitable in particular for products that are especially foamy.
Foam floating on the surface of the liquid 3 is aspirated into said chimney 47 because of the acceleration of the aspiration of the liquid 3 into the interior of the chimney 47 and the recirculation of some of the liquid in the passages 48.
In a variant shown in
As shown in this figure, the means for aerating the surface of the liquid 3 take the form of a secondary screw 50 disposed above the second anti-vortex member 40 and constrained to rotate with the shaft 14.
The pitch of the secondary screw 50 is the opposite to the pitch of the main screw 13.
The means for aerating the surface of the liquid 3 further comprise an anti-vortex member 51 disposed above the secondary screw 50 and inside a cylindrical chimney 52.
The chimney 52 is fixed to the internal edges of the reinforcing ribs 41 to form passages 55 for the liquid 3 in conjunction with the duct 12 and said reinforcing ribs 41.
The secondary screw 50 and the anti-vortex member 51 are situated between the two series of windows 21 and 22 and the chimney 52 extends substantially from the middle of the first series of windows 21 to the upper edge of the second series of windows 22.
A cover 53 is mounted on the shaft 14 above the upper edge of the chimney 52.
The vertical position of the cover 53 is adjustable to form an adjustable passage 54 in conjunction with the upper edge of the chimney 52.
The rotation of the main screw 13 causes aspiration of the liquid 3 through the windows 21 and 22 as a result of which the liquid 3 flows upward in the duct 12.
Accordingly, some of the liquid 3 is aspirated into the duct 12 through the windows 22 and some of the liquid 3 is aspirated through the windows 21 and flows downward in the passages 55 formed between the chimney 52 and the duct 12.
Moreover, because the pitch of the secondary screw 50 is the opposite of the pitch of the main screw 13, some of the liquid is aspirated upward into the chimney 52 and is sprayed into the air at the surface of the liquid 3 inside the funnel 11 on passing through the passage 54.
Spraying some of the liquid therefore incorporates air into the liquid and, moreover, reduces the formation of foam on the surface of the liquid.
The anti-vortex member 51 prevents rotation of the liquid in the chimney 52 above the secondary screw 50.
In this variant the flowrate of the liquid 3 in the duct 12 can be adjusted by moving the sleeves 25 and 26 relative to the windows 21 and 22.
In a fourth embodiment shown in
The vortex pump 60 is disposed above the second anti-vortex member 40 and at the level of the first series of windows 21.
The vortex pump 60 is driven in rotation by the shaft 14 and comprises, firstly, a circular plate 61 fixed to the shaft 14 and provided on its upper face with radial and vertical vanes 62 and, secondly, a chimney 63 fixed to the upper edge of said vanes 62.
The assembly constituted of the plate 61, the vanes 62, and the chimney 63 is retained to the shaft 14 by means of a sleeve 61a whose vertical position on the shaft 14 is adjustable.
The sleeve 61a is fixed to said shaft 14 by means of a member consisting of a fixing screw, not shown, for example.
As shown in
The chimney 63 extends toward the top of the vessel 1, substantially from the middle of the first series of windows 21 to the upper edge of the vanes 62.
The chimney 63 forms an internal passage 65 whose lower portion communicates with the interior of the duct 12 via annular passages 66 formed between the vanes 62, the ring 64, and the plate 61.
The chimney 63 is preferably conical with the narrower end facing toward the top of the vessel 1, as shown in
In a variant, the chimney 63 can be cylindrical.
The vanes 62 are plane or curved and there are preferably three of them, regularly distributed over the plate 61, as shown in
The rotation of the main screw 13 causes aspiration of the liquid 3 into the duct 12 through the windows 21 and 22 and the liquid 3 flows continuously downward in the duct 12.
Moreover, the rotation of the vortex pump 60 driven by the shaft 14, i.e. the rotation of the assembly constituted of the plate 61, the vanes 62, and the chimney 63, causes aspiration of the liquid 3 at the surface into the passage 65, with the result that the liquid then passes through the annular passages 66 and is reinjected into the vessel 1.
In this embodiment, adjustment of the flowrate of the liquid by the sleeves 25 and 26 inside the duct 12 is not necessary.
Because of the effect of the vortex pump 60, the liquid 3 is subjected to violent agitation, encouraging the incorporation of air into the liquid.
This embodiment is particularly suitable for very foamy products because the foam floating on the surface of the liquid 3 is aspirated by the vortex pump 60, which eliminates the foam quickly and efficiently.
A fifth embodiment of the device according to the invention, shown in
The single-passage screw 70 is disposed above the second anti-vortex member 40 and at the level of the first series of windows 21.
The single-passage screw 70 is driven in rotation by the shaft 14 and comprises, firstly, a circular plate 71 fixed to the shaft 14 and disposed above the level of the liquid 3 in the vessel 1 and, secondly, inside the liquid 3, a vertical plate 72 forming a spiral around the shaft 14 and fixed to the lower face of said plate 71.
As shown more particularly in
The assembly constituted of the plate 71 and the vertical plate 72 is retained to the shaft 14 by means of a sleeve 71a whose vertical position on the shaft 14 can be adjusted.
To this end, the sleeve 71a is fixed to said shaft 14 by means of a member constituted of a fixing screw, not shown, for example.
The internal edge of the vertical plate 72 includes a vertical deflector 76 inclined in the direction of the center of the spiral formed by said plate 72.
The distance between the plate 72 and the axis of the shaft 14 decreases progressively, as shown in
The rotation of the single-passage screw 70 driven by the shaft 19, i.e. the rotation of the assembly constituted of the plate 71 and the plate 72 in the direction indicated by the arrow in
The liquid is stirred inside the vertical passage 74, flows downward in the passage 74, and is evacuated into the interior of the duct 12 via the lower outlet 75.
The deflector 76 improves the stirring of the liquid inside the vertical passage 74 and prevents the liquid from returning via the lateral inlet 73.
The stirring effected by the single-passage screw 70 encourages the incorporation of air into the liquid 3.
A sixth embodiment of the device according to the invention, shown in
The two-passage screw 80 is disposed above the second anti-vortex member 40 and at the level of the first series of windows 21.
The two-passage screw 80 is driven in rotation by the shaft 14 and comprises, firstly, a circular plate 81 fixed to the shaft 14 and disposed above the level of the liquid 3 in the vessel 1 and, secondly, two vertical plates 82 and 83 inside the liquid 3.
The vertical plates 82 and 83 are fixed to the lower face of the plate 80 and each takes the form of two half-shells opposite and spaced from each other, as shown in
The two plates 82 and 83 delimit two lateral inlets 84 and 85 for the liquid, two passages 86 and 87 in which the liquid flows downward, and a lower outlet 88 for said liquid.
The assembly constituted of the plate 81 and the vertical plates 82 and 83 is retained to the shaft 14 by means of a sleeve 81a whose vertical position on the shaft 14 can be adjusted.
The sleeve 81a is fixed to the shaft 14 by means of a member constituted of a fixing screw, not shown, for example.
As shown more particularly in
The rotation of the two-passage screw 80 driven by the shaft 14, i.e. the rotation of the assembly constituted of the plate 81 and the two vertical plates 82 and 83 in the direction indicated by the arrow in
The liquid enters via the lateral inlets 84 and 85, is stirred inside the passages 86 and 87, flows downward inside the passages 86 and 87, and is then evacuated into the duct 12 through the lower outlet 88.
The deflectors 89 and 90 augment the stirring of the liquid inside the passages 86 and 87 and prevent the liquid flowing back through the lateral inlets 84 and 85.
The effect of stirring by the two-passage screw 80 encourages incorporation of air into the liquid 3.
In these last two embodiments, adjustment of the flowrate of the liquid by the sleeves 25 and 26 of the duct 12 is not necessary and these last two embodiments are more particularly used in situations where the level of liquid inside the vessel 1 varies.
A pumping screw (not shown) can be disposed on the shaft 14 below the single-passage screw or the two-passage screw to improve the flowrate of the single-passage screw 70 or the two-passage screw 80.
The device according to the invention is applied, for example, to treatment of water, urban effluent, industrial waste water, greases by biological degradation, drainage materials, livestock waste, and generally to all biodegradable industrial products.
Of course, the present invention is not limited to the embodiments described and shown, which are provided by way of illustrative and nonlimiting example.
Number | Date | Country | Kind |
---|---|---|---|
01 05292 | Apr 2001 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/FR02/01314 | 4/17/2002 | WO | 00 | 10/17/2003 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO02/085799 | 10/31/2002 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2244902 | Stich | Jun 1941 | A |
2444902 | Torsch | Jul 1948 | A |
3643403 | Speece | Feb 1972 | A |
4328175 | Roeckel et al. | May 1982 | A |
4374030 | Franklin, Jr. | Feb 1983 | A |
4699740 | Bollenrath | Oct 1987 | A |
4900480 | Litz et al. | Feb 1990 | A |
4902302 | Reid | Feb 1990 | A |
4919849 | Litz et al. | Apr 1990 | A |
5004571 | Litz et al. | Apr 1991 | A |
5108662 | Litz et al. | Apr 1992 | A |
5110510 | Norcross | May 1992 | A |
5451349 | Kingsley | Sep 1995 | A |
5512217 | Batterham et al. | Apr 1996 | A |
5846498 | Kingsley | Dec 1998 | A |
5925290 | Hills | Jul 1999 | A |
5972661 | Kubera et al. | Oct 1999 | A |
6076812 | Lisi | Jun 2000 | A |
6273402 | Cheng | Aug 2001 | B1 |
6276670 | Jacobs | Aug 2001 | B1 |
6460830 | Boulant | Oct 2002 | B1 |
Number | Date | Country |
---|---|---|
2408794 | Sep 1975 | DE |
3000395 | Jul 1981 | DE |
3427174 | May 1982 | DE |
9302204 | Aug 1993 | DE |
0687497 | Dec 1995 | EP |
2758094 | Jul 1998 | FR |
180647 | Jun 1978 | HU |
9701599 | Oct 1997 | HU |
Number | Date | Country | |
---|---|---|---|
20040155368 A1 | Aug 2004 | US |