GOBITTO, Giuseppe (Via John F. Kennedy 19, Zugliano di Pozzuolo Del Friuli, I-33050, IT)
CLAIMS
1) Self-cleaning nozzle (20) for flotation clarifϊers comprising an housing (21) which presents an inlet opening (22) and an outlet opening (25) for the liquid to be treated, and a partializing element (23) which is supported in elastically slidable and adjust- able way, characterized in that the head (29) of the said partializing element (23) is in a position opposite the said inlet opening (22) for the fluid to be treated and it is provided with grooves (39) which cooperate with grooves (40) realized in the peripheral edge of the said inlet opening (22) in order to produce a turbulent movement in the fluid to be treated, the said partializing head (29) of the said partializing element (23) is moreover adapted to slide away from the said inlet opening (22) under the pressure of the liquid to be treated, whenever the said grooves (39) and (40) need to be cleaned of clogging caused by solid particles contained in the liquid to be treated.
2) Self-cleaning nozzle (20) according to the claim 1, characterized in that the partializing head (29) has a substantially conic shape and that its peripherical side is pro- vided with a plurality of variable depth grooves (39).
3) Self-cleaning nozzle (20) secondo Ie claims 1 and 2, characterized in that the said grooves (39) in the said partializing head (29) are extending in longitudinal and rectilinear direction.
4) Self-cleaning nozzle (20) according to the claims 1 and 2, characterized in that the said grooves (39) in the partializing head (29) have a curvilinear course which is suited to produce a turbulent movement in the flow coming into contact with the grooves.
5) Self-cleaning nozzle (20) according to the previous claims, characterized in that the partializing head (29) presents a combination of rectilinear and curvilinear grooves 6) Self-cleaning nozzle (20) according to the claims from 1 to 5, characterized in that the partializing head (29) is realized in a removable way with respect to the stem (28) in order to ensure interchangeability between a plurality of partializing heads (29) which are differently shaped and grooved according to the characteristics of the liquid to be treated.
7) Self-cleaning nozzle (20) according to the claiml, characterized in that the said grooves (40) in the peripheral edge of the inlet opening (22) for the fluid to be treated present a rectilinear course.
8) Self-cleaning nozzle (20) according to the claim 1, characterized in that the said grooves (40) in the peripheral edge of the inlet opening (22) for the fluid to be treated present a curvilinear course which is suited to produce a turbulent movement in the fluid coming into contact with the grooves.
9) Self-cleaning nozzle (20) according to the claims 1, 7 and 8, characterized in that the peripheral edge of the inlet opening (22) for the fluid to be treated presents a combi- nation of rectilinear and curvilinear grooves (40).
10) Self-cleaning nozzle (20) according to the claims I 5 7, 8 and 9 characterized in that the longitudinal grooves (40) in the inlet opening (22) of the housing (21) are formed in an annular insert (41) that is removably associated with the inlet opening (22) of the housing (21) in order to ensure interchangeability between a plurality of annular inserts (41) which are differently shaped and grooved according to the characteristics of the liquid to be treated.
11) . Self-cleaning nozzle (20) according to the claims 1, 7, 8, 9 and 10 characterized in that the said annular insert (41) is equipped with peripheral projections (42) which engage by snap-action with corresponding recesses (43) in the peripheral edge of the inlet opening (22) of the housing (21). 12) Self-cleaning nozzle (20) according to the claim 1, characterized in that the flow par- tializer (23) comprises a rectilinear stem (28) and a partializing head (29), that the said stem (28) is housed, slidably in the longitudinal direction, in an eraietic liner (30) which further defines a conduit (31) that is connecting the said inlet opening (22) and the said outlet opening (25) of the housing (21), that the said partializing head (29) is placed in the said conduit (31) and it has a position opposite the said inlet opening (22) for the fluid to be treated.
13) Self-cleaning nozzle (20) according to the claim 1, characterized in that the said housing (21) is provided with an assembly opening (26) which is ermetically closable with an outer cover (27) , that an hollow cylindrical shaped bush (33) is screwed into a threaded opening (32) of the cover (27) closing the housing (21), that the inner cavity (34) of the cylindrical bush (33) is so shaped and dimensioned as to realize a sliding coupling with the free end of the stem (28) of the flow partializer (23), that a winch or a crank handle (35) is fixed to the outer surface of the said cylindrical (33) for allowing the operator to manually adjust the relative position of the bush (33) with respect to the housing (21).
14) Self-cleaning nozzle (20) according to the claim 1, characterized in that a compression spring (36) is placed around the stem (28) of the flow partializer (23) and its outer end pushes against the inner surface of the said cylindrical bush (33) in the cover (27) while its inner end pushes against a thickening (37) of the stem (28) and that the spring force can be manually adjusted by means of the said winch or the crank handle (35).
15) Self-cleaning nozzle (20) according to the claim 1, characterized in that the stem (28) of the said flow partializer (23) presents a stop collar (38) which is realized near
12 the partializing head (29) for acting as a stopping surface for the sliding movement of the stem toward the inside of the ermetic liner (30). Udine, 30 August 2007
Enologica Friulana s.a.s. The General partner
BATTELLO Paolo
13 |
Self-cleaning nozzle for flotation clarifiers Description
The invention relates to a self-cleaning nozzle for flotation clarifiers. In particular, the nozzle according to the invention is advantageously but not exclusively usable in devices for clarification by flotation of alimentary liquids such as for example the must of wine, fruit juices and the like.
The clarification of the alimentary liquids is a prefermentative working phase which permits to reduce the torbidity and the viscosity resulting from pectins and azotic substances. The reduction of the azotic substances enables to inhibit or at least to control the growth of fermenting wild yeasts in order to slow down the natural fermentation process or to enable a fermentation method controlled by addition of selected yeasts. As it is known, the process of clarification by flotation is based on the different densities of the solid and liquid particles which are to be separated in the alimentary liquid to be treated.
In particular, the rinds and the small pieces of fruit's pulp contained in the alimentary liquids to be treated, have specific gravity less than that of the liquid into which they are dispersed and, therefore, they tend to slowly float to the surface of the liquid. In order to accelerate the upwardly rising of the solid particles, the whole or a part of the liquid suspension is sucked from the containing tank by means of a centrifugal pump, it is additionated with gas (as for example ambient air, nitrogen, carbon dioxide, oxygen or the like) and then it is pumped back into the lower part of the containing tank as a froth liquid which is additionated with very small gas bubbles. In the containing tank, the gas microbubbles adhere to the solid particles surface and accelerate the rising of the solid particles towards the surface of the liquid suspension. The microbubbles behave like a fil-
ter which, by rising into the containing tank, retains suspended particles, microorganisms and azotic substances and forms a brown coloured layer of lees, called "cap", on the surface of the alimentary liquid. After the clarification by flotation process, the must under the layer of lees is clear and it may be drawn through a drain opening in the lower part of the containing tank and it may be transferred to the subsequent phases of fermentation. The European Patent EP 1106257 discloses a device for gas-saturating a liquid suspension to be supplied to a flotation clarifϊer.
The alimentary liquid follows a tortuous path through a diffuser which mixes the gas into the liquid mass and ejects a gas-liquid mixture following divergent directions. The device houses an obturator the head of which has channels running through it while the stem of the obturator has a spring which pushes the head of the obturator in its closed position. The force of the spring can be adjusted by means of a bolt nut which is screwed onto the threaded end of the stem in order to adapt the diffuser to various liquids to be clarified and to the various operating conditions (fiowrate, pressure, etc.) which may be required in each case.
This kind of devices present the drawback that the chambers in the housing of the obturator as well as the channels passing through the head of the obturator can easily get clogged with the solid particles ( grape-stones, small pieces of pulp and skin, etc.) in the alimentary liquid to be clarified. The clogged channels cause a fall in the working pressure and malfunctioning conditions of the clarification apparatuses. Therefore, the operator is compelled to stop the clarification process, to open the device, to extract the obturator, clean up the housing of the obturator, to clear the channels passing through the head of the obturator then to reassemble all components in order to restart the flotation process.
It appears clear that this drawback lenghtens the duration of the flotation process because it requires numerous cleaning interventions manually performed by the operator, particularly during the treatment of alimentary liquids which are extremely cloudy and viscous. A further drawback derives from the fact that the treatment of alimentary liquids which are extremely cloudy and viscous requires a filtering device installed upstream of the rotary pump. This filtering device suffers from frequent clogging problems which cause cavitation and vibration phenomenons in the rotary pump and a rapid wear of its functional components. Therefore, it is a primary object of the present invention to overcome the above-described drawbacks and limitations of the known devices by providing a self-cleaning nozzle which reduces the duration of the flotation process and minimizes the manual interventions of the operator which is assigned to controll the correct running of the process. Another object of the present invention is to provide a nozzle having an essential structure which can be simply disassembled also by not specialized personnel. Finally, a further object of the present invention is to provide a nozzle which can be easily and rationally adapted to different kinds of alimentary liquids to be trated with the clarification by flotation process, thereby rendering superfluous the installation of filtering devices upstream of the rotary pump. These and other objects are attained according to the invention by a nozzle having the hereinafter claimed features.
The aims and features of the nozzle according to the invention will now be described with reference to the accompanying drawings in which:
- the Figure 1 is a longitudinally sectioned view of the nozzle according to the invention;
- the Figure 2 is a front perspective view of the partializing head of the nozzle of Fig. 2;
- the Figure 3 shows a front perspective view of an alternative embodiment of the partial- izing head of the nozzle of Fig. 2;
- the Figure 4 is a perspective view of the inlet opening of the housing of the nozzle;
The nozzle 20 according to the invention comprises a flow partializer 23 which is seated within an housing 21 as to be slidable in the longitudinal direction.
The inlet opening 22 of the housing 21 is connected to the outflow conduit of a rotary pump24.
The suction side of the rotary pump 24 is connected, by means of a suction conduit which is not shown in the Figures, to an out-take opening which is realized in the lower part of the tank containing the alimentary liquid to be clarified.
In a well known manner, the suction conduit comprises a plurality of openings for introducing in the alimentary liquid the treating gas as well as coadiuvant substances for the clarification by flotation process. The outlet opening 25 of the housing 21 is connected, by means of a conduit which is not shown in the Figures, to a return opening also realized in the lower part of the tank containing the alimentary liquid to be clarified.
The housing 21 is provided with an assembly opening 26 which is ermetically closable with an outer cover 27 that can be easily removed for allowing the periodical maintenance operations of the device. The flow partializer 23 comprises a rectilinear stem 28 and a partializing head 29.
The stem 28 is housed slidably, in the longitudinal direction, in an ermetic liner 30 which further defines a conduit 31 that is connecting the inlet opening 22 and the outlet opening of the housing 21. An hollow cylindrical shaped bush 33 is screwed into a threaded opening 32 of the cover 27 closing the housing 21.
The inner cavity 34 of the cylindrical bush 33 is so shaped and dimensioned as to realize a sliding coupling with the free end of the stem 28 of the flow partializer 23. A winch or a crank handle 35 is fixed to the outer surface of the cylindrical bush 33 allowing the operator to manually adjust the relative position of the bush 33 with respect to the housing 21.
A compression spring 36 is placed around the stem 28 of the flow partializer 23 and its outer end pushes against the inner surface of the cylindrical bush 33 in the cover 27 while its inner end pushes against a thickening 37 of the stem 28. The spring force can be manually adjusted by means of the winch or the crank handle 35. The flow partializer 23 presents a stop collar 38 which is realized near the partializing head 29 for acting as a stopping surface for the sliding movement of the stem toward the inside of the eπnetic liner 30.
It is to be pointed out that the partializing head 29 has a substantially conic shape having its vertex in a position opposite the said inlet opening 22 of the housing 21. Moreover, a plurality of longitudinal grooves 39 are provided on the peripheral side of the partializing head . With particular reference to the Figure 2, each of said grooves 39 follows a substantially rectilinear direction and has a variable depth. As clearly shown in the Figure 3, the said grooves may also be realized with a curvilinear shape that is able to produce a turbulent movement in the flow coming into contact with the grooves.
According to a further alternative embodiment, the partializing head 29 may have a combination of rectilinear and curvilinear grooves 39.
With particular reference to the Figure 4, further longitudinal grooves 40 can be realized in the peripheral edge of the inlet opening 22 of the housing 21 and on the side looking towards the nozzle 20. The said grooves 40 may be alternatively used instead of the said
grooves 39 of the partializing head 29 or said grooves 40 may be associatedly used with the grooves 39.
Moreover, it is to be pointed out that the partializing head 29 can be realized in a removable way with respect to the stem 28 in order to ensure interchangeability between a plu- rality of partializing heads 29 which are differently shaped and grooved according to the characteristics of the liquid to be treated.
For example, the partializing head 29 can be provided with an innerly threaded opening which is adapted to be screwed onto a corresponding threaded end of the stem 28. The longitudinal grooves 40 in the inlet opening 22 of the housing 21 can also be formed in an annular insert 41 that is removably associated with the inlet opening 22 of the housing 21. For example, the annular insert 41 can be equipped with peripheral projections 42 which engage by snap-action with corresponding recesses 43 in the peripheral edge of the inlet opening 22 of the housing 21. Similarly to the partializing head 29, it can be possible to provide a plurality of annular inserts 41 which are differently shaped and grooved according to the characteristics of the liquid to be treated.
The nozzle 20 according to the invention operates in the following way. The liquid to be clarified enters the housing 21 through the inlet opening 22 ,in the direction indicated by the arrow, it impacts against the conic shape of the partializing head 29, following a direction from the vertex to the base of the conic shape, and it exits the housing 21 through the outlet opening in the direction indicated by the arrow. Laboratory tests have shown that the longitudinal grooves 39 of the partializing head 29, associatedly used with the longitudinal grooves 40 or alternatively used to said longitudinal grooves 40 in the inlet opening 22 of the housing, can sensibly improve the mixing be-
tween gas and the liquid to be treated and they favour an homogeneous formation of gas microbubbles in the liquid mass returned to the containing tank. During a working process, the operator can manually adjust the correct working pressure by turning the winch or the crank handle 35 and counterbalancing the pressure of the ali- mentary liquid on the conic partializing head 29.
In the case that the annular passage, defined by the partializing head 29 and the inlet opening 22 of the housing 21, is blocked by the solid particles suspended in the liquid, the pressure of the alimentary liquid causes the sliding displacement of the stem 28 and of the partializing head 29 away from the inlet opening 22 of the housing 21 until the ob- stracting solid particles are well dispersed.
In the case of an important blockage that can not be solved by the self cleaning action of the nozzle 20, the operator turns the winch or the crank handle 35 for reducing the force of the compression spring and for enlarging the sliding displacement of the stem 28 away from the inlet opening 22 of the housing 21. From what stated, it will be seen that the nozzle 20 according to the invention achieves the primary object of producing a self cleaning effect which allows to reduce the flotation process duration and to minimize the interventions of the operator which is assigned to controll the correct running of the process. Moreover, the nozzle 20 according to the invention has an essential structure which can be simply disassembled also by not specialized personnel.
It is to be pointed out that the nozzle 20 according to the present invention can be advantageously and rationally adapted to different kinds of liquids to be clarified thanks to the interchangeability of the partializing head 29 and of the grooved insert 41 in the inlet opening 22 of the housing.
It is well understood that modifications and variations may be made to the nozzle 20 forming the object of the present invention without departing however from the scope defined by the following claims with reference to the accompanying drawings and thence from the protection extent of the present industrial invention.
Next Patent: POLYMORPHS OF 3- ( ( (4-TERT-BUTYL-BENZYL) - (PYRIDINE-3-SULFONYL) -AMINO) -METHYL) -PHENOXY) -ACETI...