ITBO20090723A1 - ELICA GROUP - Google Patents

Description

MELLONI ALFREDO

Description of Industrial Invention Patent entitled:

"PROPELLER GROUP".

TECHNICAL FIELD OF THE INVENTION

The present invention relates to a propeller unit.

STATE OF THE PRIOR ART

It is known that the propellers of airplanes, or of other devices that operate at low temperatures such as snow guns, present among the main technical problems to be solved that of preventing the formation of surface ice, especially but not exclusively along the edges of attachment of the blades, or on the surface of the hub.

This formation of ice, when particularly consistent and not adequately prevented, can generate anomalous vibrations in the propeller, which is rotating at a high number of revolutions, which can also cause serious damage and breakage, which in some situations become very dangerous. also for the safety of people.

In these critical conditions the operators are forced to stop the rotation of the propeller to remove the ice: this means that, in the case of a snow generator, it is necessary to stop the production plant for a certain time, with evident economic damage.

In the particular case of snow guns, for example, the propeller of the generator usually reaches, in operation, even very low temperatures; in the presence of atmospheric conditions characterized by temperatures close to 0 ° C and high humidity, the droplets of water suspended in the air are deposited on the surfaces of the blades and the hub, and tend to form ice plates that grow quickly.

Various solutions are currently adopted to prevent the formation of ice, each of which has some not negligible drawbacks. A first type of solution consists in the use of electrical resistances positioned in seats provided in each blade and / or in the hub of the propeller; these resistances, when crossed by a suitable electric current, heat the critical surfaces up to a temperature such as to prevent the formation of ice germs. This solution is usually considered sufficiently reliable in all applications that use a propeller that operates at low temperatures, but is characterized by a rather high cost, due both to the electrical components to be mounted and to the additional machining to be carried out in the blades and / or in the hub, such as for example the predisposition of the seats for the resistances.

Another type of solution, much cheaper but also much less reliable, consists in the distribution, on the surfaces of the blades and / or the propeller hub, of disposable anti-ice substances. These substances are usually alcohol-based: a typical example of these substances is pure polypropylene alcohol or mixed with ethylene glycol.

These substances are usually sprayed on the surfaces of the propeller before it is put into operation. Even using generous quantities of substance, there is no guarantee that the anti-icing effect will last over time, which evidently tends to vanish due to evaporation of the substance itself.

In this way, the operators note the disappearance of the anti-ice effect precisely because they perceive anomalous vibrations in the machine: at this point, they are however forced to stop the rotation of the propeller to remove the ice plates that have formed in the meantime.

AIMS OF THE INVENTION

The technical task of the present invention is therefore to improve the current state of the art. Within the scope of this technical task, it is an aim of the present invention to develop a propeller unit that allows the effective prevention of surface ice formation.

Another object of the present invention is to make available a propeller assembly which can guarantee the regular operation of the machine or device in which it is installed without the need for rotation stops to remove the surface ice. A further object of the present invention is to provide a propeller unit which can guarantee safe and reliable operation of the machine or device in which it is installed.

Still another object of the present invention is to provide a propeller assembly of higher quality and lower cost than traditional ones.

These and other objects are all achieved by the propeller assembly comprising a hub and at least one blade according to one or more of the attached claims.

An important advantage achieved by the propeller assembly according to the present invention consists in the fact that the surface formation of ice is significantly reduced with respect to propellers of the traditional type.

Another advantage achieved by the propeller unit according to the present invention consists in the fact that it can guarantee regularity and reliability of operation which are much higher than traditional propellers, and therefore the safety stops for removing the ice are reduced to a minimum or almost completely eliminated. .

Another advantage achieved by the propeller unit according to the present invention consists in the fact that, while providing functional results that are qualitatively much higher than those of the traditional type propellers, it has a significantly lower cost, since the need to install additional devices is completely eliminated. anti-ice.

BRIEF DESCRIPTION OF THE DRAWINGS.

These and further advantages will be better understood by every person skilled in the art from the following description and from the attached table of drawings, given as a non-limiting example, in which:

Figure 1 is a perspective view of the propeller assembly according to the invention;

- figure 2 is a partially cut-away detail of figure 1;

Figure 3 is a perspective view of one of the blades of the propeller unit;

- figure 4 is a partially cut-away detail of figure 3.

FORMS OF IMPLEMENTATION OF THE INVENTION.

With reference to the attached figure 1, the reference numeral 1 generally indicates a propeller unit according to the invention.

The propeller unit 1 according to the invention can be mounted on any machinery such as for example a snow generator, or even on the engine of an aircraft, without any limitation.

The propeller unit 1 according to the invention turns out to be particularly effective and advantageous, as will become clear later, in situations in which it has to work at low temperatures, whether these temperatures are due to high altitudes, as in the case of installation on an aircraft, whether they are due to the winter climate, as in the case of installation on a snow generator.

The propeller unit 1 is made, for example, of metallic material: this metallic material can be an aluminum alloy. However, the unit can also be made of another material with suitable mechanical characteristics.

The unit 1 shown in Figure 1 comprises, in a per se known and traditional way, a hub 2 shaped for example substantially as an ogive, in which one of its rear portion 3 can be connected to actuation means, not shown, present in the machinery in question. which the unit itself is installed, means which may consist for example of a motor. The hub 2 can, of course, have any size and shape. The hub 2 has seats 4 for mounting a certain number of blades 5, which can be for example fixed or orientable.

Each blade 5 comprises a twisted body 6 which can obviously have any size and shape, in relation to the specific application requirements and without limitations.

The twisted body 6 comprises a connecting portion 7 to a cylindrical shank 8 for fixing in a respective seat 4 of the hub 2.

The tang 8 is equipped with means for coupling 9 to the hub 2, of an essentially known type: such coupling means 9 can comprise for example a hole for inserting a pin, a pin, or other known equivalent means not shown in the figures. .

With particular reference to Figure 2, the propeller assembly 1 comprises an external surface 10 which, according to the invention, has at least one portion covered with at least one layer 11 of permanent non-stick coating.

In an embodiment of the propeller assembly 1 according to the present invention, the permanent non-stick layer 11 is applied to the external surface 10 of the hub 2, or even only to a portion thereof.

In another embodiment of the propeller assembly, the layer 11 is applied to the outer surface 10 of the twisted body 6 of each blade 5, or even only to a portion of said outer surface 10, such as the leading edge; the layer 11 can also be applied only to one or some of the blades 5 of the propeller assembly.

In yet another embodiment of the propeller assembly, the layer 11 of permanent non-stick coating is applied to the outer surface 10 of both the hub 2 and the blades 5, or only to portions of these.

The layer 11 of permanent non-stick coating applied to the external surface 10 of the helix assembly is advantageously adapted to prevent the surface formation of ice germs. In other words, the layer 11, thanks to its composition and also thanks to the application technologies on the external surface 10, forms a sort of protective film on which the water droplets or ice particles that are deposited, and which <'> on traditional surfaces they would tend to form germs, they do not adhere but slide away driven by the aerodynamic pressure due to the rotation of the hub 2.

More in detail, the layer 11 is constituted by a composite material comprising ceramic nanoparticles.

Said composite material comprises, in an embodiment of the helix assembly, silicon dioxide (Si02). In another embodiment of the helix assembly, the non-stick composite material comprises aluminum oxide (AI2O3).

In another embodiment of the helix assembly, the non-stick composite material comprises titanium dioxide (Ti02)

In yet another embodiment of the helix assembly, the non-stick composite material comprises zirconia.

In another embodiment of the helix assembly, the composite material comprises inorganic pigments.

In yet another embodiment of the helix assembly, the non-stick composite material comprises, in varying percentages in relation to the specific application requirements, silicon dioxide, aluminum oxide, titanium dioxide, zirconia, inorganic pigments.

The layer 11 of non-stick composite material, comprising ceramic nanoparticles, has a thickness comprised between 10 µm and 50 µm; more particularly, in an embodiment of the helix assembly according to the invention, this thickness is comprised between 25 µm and 35 µm.

The composite material is obtained, for example, with "sol-gel" technology.

A composite material of this type is known under the trade name "ZV1".

The process for applying the composite material comprising ceramic nanoparticles comprises a step of degreasing the external surface 10 of the hub 2 and / or the twisted body 6 of one or more blades 5; this degreasing step can be carried out, for example, in perchlorethylene vapors.

The process then provides for a shot blasting step of the external surface 10 of the hub 2 and / or of the twisted body 6 of one or more blades 5; this shot blasting phase can be performed with corundum, with a preparation roughness of 2-4 Ra.

The process then comprises a step of applying the coating layer 11 of non-stick composite material to the external surface 10.

The process also provides for a step of firing the hub 2 and / or the twisted body 6 of one or more blades 5, after the application of the layer 11 of composite material, carried out at 20 ° C for a time of 20 minutes. Once the process of applying the layer 11 of composite material has been completed, which may also include other steps not described as they are known per se, a hub or blade is obtained for a propeller unit whose surface is distinguished, thanks to the presence of nanoparticles ceramics, with physical and mechanical properties such as to prevent, during the operation of the propeller in low temperature and high humidity environments, the formation of ice germs in the most critical surface areas: consequently, the formation of ice is completely or almost completely blocked. typical ice plates that can be seen on traditional-type propellers. As already mentioned previously, in fact, the droplets of water or the particles of ice which, suspended in the air, are deposited on the coating layer 11 of the hub and / or blade, do not adhere but slide off very easily and without the need for any external mechanical action, thanks simply to the aerodynamic pressure due to the rotation of the group at high speed. This sliding effect of even very small particles or drops prevents, consequently, the occurrence of phenomena of deposition of ice plates and their progressive growth up to generating vibrations of such amplitude as to have to stop the rotation of the unit.

With this solution important technical advantages are evidently achieved.

A first technical advantage consists, as mentioned, in the fact that the external surface of the propeller unit, and therefore of the hub and / or blade, remains, during operation and also for prolonged times, substantially clean from the formation of germs and / or ice plates.

A further technical advantage consists in the fact that, by using a propeller unit provided with a hub and / or blades according to the present invention, the stopping times of the unit for removing the ice can be eliminated or drastically reduced.

Another technical advantage consists in the fact that the machines equipped with the propeller unit according to the present invention operate more safely and reliably than those of the traditional type since vibratory phenomena which can lead to dangerous breakages are not generated during operation.

Yet another technical advantage consists in the fact that the propeller unit according to the present invention has superior quality and reliability together with a much lower cost than that of traditional type units, as it is completely devoid of anti-ice auxiliary devices and systems such as resistors. electric heaters and the like.

Furthermore, it has been observed that the propeller unit according to the present invention, together with the fact that it has the aforementioned non-stick surface property for the water and / or ice particles, is also characterized by generally superior mechanical properties, particularly as regards hardness. surface and corrosion resistance. In another embodiment of the propeller assembly according to the present invention, the permanent non-stick coating layer comprises a material of the type known commercially as Teflon® PTFE. Also this material shows characteristics and surface properties such as to prevent the adhesion of drops or ice particles, achieving the advantages listed above.

It has thus been seen how the invention achieves the proposed aims.

The present invention has been described according to preferred embodiments, but equivalent variants can be conceived without departing from the scope of protection offered by the following claims.

Claims (14)

CLAIMS 1. Shovel for propeller assembly, characterized in that at least a portion of its outer surface (10) is covered with at least one layer (11) of permanent non-stick coating. 2. Shovel according to claim 1, wherein said layer (11) of non-stick permanent coating comprises a composite material comprising ceramic nanoparticles adapted to prevent the surface formation of ice germs. 3. A blade according to claim 2, wherein said composite material comprises silicon dioxide. 4. A blade according to claim 2, wherein said composite material comprises aluminum oxide. 5. A blade according to claim 2 wherein said composite material comprises titanium dioxide. 6. A blade according to claim 2, wherein said composite material comprises zirconia. 7. Shovel according to claim 1, wherein said layer (11) of permanent non-stick coating comprises Teflon® PTFE adapted to prevent the surface formation of ice germs. 8. Hub for propeller assembly, characterized in that at least a portion of its outer surface (10) is covered with at least one layer (11) of permanent non-stick coating. Hub according to claim 8, wherein said layer (11) of non-stick permanent coating comprises a composite material comprising ceramic nanoparticles adapted to prevent the surface formation of ice germs. 10. Hub according to claim 9, wherein said composite material comprises silicon dioxide. 11. Hub according to claim 9, wherein said composite material comprises aluminum oxide. 12. Hub according to claim 9, wherein said composite material comprises titanium dioxide. 13. Hub according to claim 9, wherein said composite material comprises zirconia. 14. Hub according to claim 8, wherein said layer (11) of permanent non-stick coating comprises Teflon® PTFE adapted to prevent the surface formation of ice germs.