ITTO20120098A1 - ASPIRATOR DEVICE PERFECTED WITH ELECTROMAGNETIC OPERATION - Google Patents

Description

DESCRIPTION

of the patent for industrial invention entitled:

"PERFECTED SUCTION DEVICE WITH ELECTROMAGNETIC OPERATION"

TECHNICAL FIELD OF THE INVENTION

The present invention relates, in general, to an improved suction device with electromagnetic operation and, in particular, to a motorized wind-drivable turbine exhaust fan.

STATE OF THE ART

COITI is known, the air exchange inside buildings should be guaranteed 24 hours a day, but often the systems used for this purpose are expensive both in terms of purchase cost and in terms of energy consumption.

Known systems for the exchange of air that are not affected by the aforementioned disadvantages are the so-called wind-drivable turbine exhaust fans which enhance the natural extraction of air from the environments by exploiting natural ventilation and which represent an updated version of the so-called wind chimneys of millenary tradition.

In particular, as is known, a wind turbine aspirator is an exhaust system operated by the wind that works through the thermal differential between inside and outside. Wind turbine vacuum cleaners are particularly suitable for industrial buildings as they help to extract toxic gases and polluted air, while in civil buildings they are useful to ensure good air exchange and to eliminate condensation that forms especially in the months. winter.

Wind turbine vacuum cleaners, in addition to having a low cost and not requiring an external power supply, have the following additional advantages:

• they do not require maintenance; And

• they also act as chimney sweeps as they allow to keep the flues on which they are installed clean.

Moreover, the laws of some countries guarantee tax breaks for those who install wind turbine vacuum cleaners, since these systems exploit wind energy which is renewable energy, that is, it is a so-called clean energy.

In addition, wind turbine vacuums are much quieter than other types of air exchange systems.

Figure 1 shows a typical wind turbine vacuum cleaner, which is indicated as a whole with 10 and which includes:

• an internally hollow base structure designed to be fixed to an exhaust duct or to a flue or to an air vent (for simplicity not shown); and

• a blade suction structure 12, called a turbine or, sometimes, a cap, that is

configured and coupled to the base structure 11 in such a way as to be rotatable about an axis,

designed in such a way as to be rotatable by the wind, e

designed for, when rotationally operated, to suck or extract air from the exhaust duct or the flue or the air vent to which the wind turbine aspirator is coupled, or on which it is installed 10. The rotation of the turbine 12 induced by the wind determines a suction effect which considerably improves the draft of the exhaust duct or of the flue or of the aeration mouth on which the wind turbine aspirator 10 is installed, thus increasing the volume of extracted air.

Typically, wind turbine vacuums are made of copper, galvanized steel or aluminum and are subjected to anti-corrosion and anti-rust treatments.

The turbines of currently known wind turbine aspirators have diameters typically comprised between 360 mm and 800 mm.

The wind turbine aspirators can be advantageously installed on any type of roof or roof and in any position, even if the most used is the ridge where the connection with the roof is easier. The installation of a wind turbine aspirator on a flue does not create particular problems as long as the lateral dimensions of the wind turbine extractor are not smaller than the lateral dimensions of the upper end of the flue.

The average efficiency area of a typical wind turbine vacuum cleaner normally has a radius of 4 m and, therefore, it would be optimal to install wind turbine vacuum cleaners no more than 7 m apart from each other.

The number of wind turbine aspirators to be installed to ventilate an environment depends on the type of environment to be ventilated, in particular on the number of occupants of that environment, the type of activities carried out in that environment and the heat generated inside, or received (for example by solar radiation) from this environment.

Currently in hot countries, wind turbine aspirators with turbines having diameters of about 800 mm.

In the event of high insolation with the simultaneous absence of wind, the wind turbine vacuum cleaners are unable to guarantee adequate air exchange. For this reason it is necessary to install a large number of wind turbine aspirators on buildings so that, in the evening, hoping for a sufficient thermal gradient, it is possible to extract the accumulated stagnant air as quickly as possible.

Therefore, based on what has just been described, wind turbine vacuum cleaners do not work or do not work properly in the absence of wind and with an insufficient thermal gradient.

In consideration of the fact that in some particular situations, both in the civil sector (think, for example, of the ventilation of blind bathrooms) and in the industrial sector (think, for example, of poultry deposits, tanneries, etc.), it is necessary to guarantee a 24-hour exchange of air, in recent years motorized wind turbine aspirators have also been developed.

In this regard, Figure 2 shows a typical motorized wind turbine aspirator, which is indicated as a whole with 20 and which comprises:

• a base structure 21 functionally similar to the base structure 11 of the wind turbine aspirator 10 previously described and illustrated in Figure 1;

• a wind turbine 22 functionally similar to the wind turbine 12 of the wind turbine aspirator 10; and an electric motor 23 which is

disposed externally to the turbine 22, and configured to rotate the turbine 22 by means of a drive shaft 24 coupled to said turbine 22.

The power supply to the electric motor 23 can be supplied by the electrical network and / or, as illustrated in Figure 2, by a photovoltaic system 25 coupled to the electric motor 23 and configured to generate electrical energy by means of one or more photovoltaic panels 26. In In the case of a mixed power grid / photovoltaic system, the electricity produced by the photovoltaic system 25 can be used during the day and that supplied by the electricity grid at night, thus obtaining a certain energy saving.

For reasons of space, the electric motor 23 can be applied exclusively to aspirators with turbines having a diameter typically not greater than 360 mm. In fact, to be able to motorize aspirators with turbines having larger diameters it would be necessary to use a very bulky, very expensive and high aesthetic impact support structure; moreover, the electric motor necessary to rotate the turbine would in this case be excessively expensive and would require a more complex maintenance.

Motorized wind turbine aspirators of the known type have the following disadvantages:

• the presence of the motor means that motorized wind turbine vacuum cleaners have a larger footprint and change the aesthetics of the buildings on which they are installed more than non-motorized wind turbine vacuum cleaners; therefore motorized wind turbine aspirators cannot be installed on buildings subjected to particular architectural / aesthetic constraints (think, for example, of buildings of historical interest);

• motorized wind turbine vacuum cleaners have a higher cost than non-motorized wind turbine vacuum cleaners; And

• motorized wind turbine aspirators, unlike non-motorized wind turbine aspirators, require constant periodic maintenance (for example for the replacement of motor bearings stressed transversely by the action of the wind).

Furthermore, the motors of the motorized wind turbine aspirators of the known type, if the latter are used to extract hot fumes, for example from fireplaces, furnaces, etc., require a lot of maintenance due to wear due to the high temperatures generated. from such fumes.

OBJECT AND SUMMARY OF THE INVENTION

The object of the present invention is therefore to provide a suction device which is able to alleviate, at least in part, the aforementioned disadvantages of the known type of motorized wind turbine aspirators.

The aforesaid object is achieved by the present invention as it relates to a suction device, as defined in the attached claims.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the present invention, some preferred embodiments, provided purely by way of non-limiting explanatory example, will now be illustrated with reference to the attached drawings (not to scale), in which:

Figure 1 illustrates a known type of wind turbine aspirator;

Figure 2 illustrates a known type of motorized wind turbine aspirator;

Figure 3 shows a motorized wind turbine aspirator according to a first preferred embodiment of the present invention;

Figure 4 shows a cross section of a specific portion of the aspirator shown in Figure 3;

Figure 5 shows an alternative embodiment of a component of the aspirator shown in Figures 3 and 4;

Figure 6 shows a cross section of a specific portion of a motorized wind turbine aspirator according to a second preferred embodiment of the present invention; And

Figure 7 shows the aspirator made in accordance with said second preferred embodiment of the present invention and comprising a photovoltaic panel fixed on the wind turbine.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION

The following description is provided to enable a person skilled in the art to make and use the invention.

Various modifications to the presented embodiments will be immediately evident to skilled persons and the generic principles disclosed herein could be applied to other embodiments and applications without, however, thereby departing from the scope of protection of the present invention.

Therefore, the present invention must not be understood as limited only to the embodiments described and shown, but it must be granted the widest scope of protection consistent with the principles and characteristics presented here and defined in the attached claims.

In order to describe the present invention in detail, figure 3 shows a motorized wind turbine aspirator made according to a first preferred embodiment of the present invention and indicated as a whole with 30.

In particular, Figure 3 shows a perspective view of the motorized wind turbine aspirator 30 which comprises:

• an internally hollow base structure 31 designed to be fixed to an exhaust duct or to a flue or to an air vent (for simplicity not shown); and

• a suction structure 32, conveniently with blades, hereinafter referred to for simplicity as a wind turbine or just a turbine, which is

configured and coupled to the base structure 31 in such a way as to be rotatable about a respective central axis,

designed in such a way as to be rotatable by the wind, e

designed to, when rotatably operated, suck in, or extract, air from the exhaust duct or from the flue or from the aeration mouth through the base structure 31. In detail, the base structure 31 includes a first portion 311 which in the example of figure 3 has the shape of a truncated pyramid which extends around a respective central axis and which comprises a major square base 311a and a minor circular base which are perpendicular to said respective central axis. Said first portion 311 includes a square opening on the major base 311a and a circular opening on the minor base. In use, the base structure 31 is fixed to the exhaust duct or to the flue or to the aeration mouth in such a way that the air sucked in by said exhaust duct or said flue or said aeration mouth enters the aspirator 30 through the square opening on the major base 311a of the first portion 311 of said base structure 31.

Furthermore, the base structure 31 also includes a second portion 312 which in the example of Figure 3 has the shape of a right circular cylinder extending from the minor base from the first portion 311 around a respective central axis which represents an extension of the central axis of the first portion 311. Therefore, the first 311 and the second portion 312 are coaxial and the respective central axes identify a central axis of the entire base structure 31. Furthermore, said second portion 312 comprises a first circular opening on the base coupled to the smaller base by the first portion 311 and a second circular opening on the other base. Said bases of the second portion 312 are perpendicular to the respective central axis, or to the central axis of the base structure 31. In the following, said second portion 312 will be called, for simplicity of description, collar.

The wind turbine 32 is internally hollow and includes an outer portion extending outward of the base structure 31 and an end portion extending from the outer portion to the interior of the base structure 31 through the second opening of the collar 312. In particular, the turbine 32 extends, and in use rotates, around a respective central axis which overlaps and extends the central axis of the base structure 31. Therefore, the base structure 31 and the wind turbine 32 turn out to be coaxial. In detail, the end portion of the turbine 32 has a rotational symmetry with respect to, and extends, and in use rotates, around a lower portion of the central axis of said turbine 32, said lower portion being superimposed on an upper portion of the central axis of the base structure 31.

In order to describe in more detail the operation of the aspirator 30, figure 4 shows a cross section of the end portion of the wind turbine 32 in a plane which is perpendicular to the central axis of said turbine 32.

In particular, the end portion of the wind turbine 32 is indicated in Figure 4 with 321, while the central axis of said turbine 32 is indicated with 0.

In detail, the aspirator 30 also comprises an electric motor which is configured to rotate the turbine 32 and which includes:

• magnetic means that are

fixed around the end portion 321 of the turbine 32 along a circumference which lies on a plane perpendicular to the central axis 0 and which is centered on said central axis 0, and

configured to generate first predefined magnetic fields in predefined positions along said circumference; and

• a control module 41 which is fixed to the base structure 31 and is configured to generate second predefined magnetic fields such as to repel or attract the magnetic means and, therefore, such as to cause a rotation of the end portion 321 of the turbine 32 and, hence, of the entire turbine 32 around the central axis 0.

Conveniently, the magnetic means are fixed on an external surface of the side wall of the end portion 321 of the turbine 32 in such a way as to face towards an internal surface of the side wall of the collar 312, while the control module 41 is fixed to the side wall of the collar 312 (for example as shown in Figure 3, externally thereto) in correspondence with the magnetic means fixed around the end portion 321.

In the example of Figure 4, the magnetic means comprise a plurality of permanent magnets 42 each of which is arranged in a respective position around the end portion 321 of the turbine 32 and is configured to generate a predefined magnetic field. In particular, the permanent magnets 42 are arranged around the end portion 321 of the turbine 32 along a circumference which lies on a plane perpendicular to the central axis 0 and which is centered on said central axis 0 in such a way that each chord joining the centers of two adjacent permanent magnets 42 along said circumference have the same predetermined length.

Alternatively, the magnetic means may conveniently comprise a ferrite ring which includes sectors which are magnetized so as to each generate a predefined magnetic field. In particular, each magnetized sector of said ferrite ring is comprised between two non-magnetized sectors. Furthermore, the magnetized sectors are arranged along the ferrite ring in such a way that each string joining the centers of two adjacent magnetized sectors along said ferrite ring has the same predetermined length.

In this regard, Figure 5 shows a ferrite ring 50 which comprises magnetized sectors 51 and non-magnetized sectors 52 and which can be conveniently fixed around the end portion 321 of the turbine 32 to realize said magnetic means.

Referring to Figure 4, the control module 41 includes:

• a first electromagnet 411;

a second electromagnet 412;

a Hall effect sensor 413; and

• an electronic control unit 414 connected to the Hall effect sensor 413 and to the two electromagnets 411 and 412.

In the example of figure 4, the first electromagnet 411, the second electromagnet 412 and the Hall effect sensor 413 are arranged along an arc of a circumference which lies on a plane perpendicular to the central axis 0 and which is centered on said central axis 0 in such a way that the Hall effect sensor 413 is adjacent, along said arc of circumference, to the first electromagnet 411 and that the second electromagnet 412 is adjacent, along said arc of circumference, to the first electromagnet 411. In particular, the first electromagnet 411, the second electromagnet 412 and the Hall effect sensor 413 are arranged along said arc of circumference in such a way that the string that joins the centers of the first electromagnet 411 and of the second electromagnet 412 and the rope that joins the centers of the effect sensor Hall 413 and of the first electromagnet 411 have the aforementioned predefined length.

The Hall effect sensor 413 is configured to measure the intensity of a surrounding magnetic field, ie in which said sensor 413 is immersed. In particular, the Hall effect sensor 413 is configured to measure the intensity of the magnetic field generated by the means magnetic, i.e. by the permanent magnets 42 or by the magnetized sectors 51 of the ferrite ring 50.

Furthermore, the electronic control unit 414 is configured for:

• receiving from the Hall effect sensor 413 an electrical signal indicative of the magnetic field intensity measured by said sensor 413;

• determine, on the basis of the electrical signal received by the Hall effect sensor 413, a position of the magnetic means with respect to the Hall effect sensor 413 and, therefore, also with respect to the first electromagnet 411 and to the second electromagnet 412 (since the electronic unit control 414 "knows" the aforementioned predefined distance between the adjacent permanent magnets 42 or the adjacent magnetized sectors 51, between the Hall effect sensor 413 and the first electromagnet 411, and between the first electromagnet 411 and the second electromagnet 412); and, • on the basis of the determined position, actuate the first electromagnet 411 or the second electromagnet 412 in such a way that the driven electromagnet generates a magnetic field such as to repel or attract the magnetic means and, therefore, such as to cause a rotation of the portion end 321 of the turbine 32 and, therefore, of the entire turbine 32 around the central axis 0.

For example, in the situation shown in Figure 4, the electronic control unit 414 determines, on the basis of the electrical signal received by the Hall effect sensor 413, that a first permanent magnet 42 is placed in front of the Hall effect sensor 413 and, therefore , also that a second permanent magnet 42 is placed in front of the first electromagnet 411 and a third permanent magnet 42 is placed in front of the second electromagnet 412.

Therefore, the electronic control unit 414 operates the first electromagnet 411 in such a way that said first electromagnet 411 generates a magnetic field such as to reject said second permanent magnet 42 and, therefore, such as to cause an anti-clockwise rotation of the turbine 32 around to the central axis 0.

When, on the basis of the electrical signal received by the Hall effect sensor 413, the electronic control unit 414 determines that the first permanent magnet 42 and the second permanent magnet 42, thanks to the rotation of the turbine 32 around the central axis 0, are having reached halfway, respectively, between the Hall effect sensor 413 and the first electromagnet 411, and between the first electromagnet 411 and the second electromagnet 412, said electronic control unit 414 turns off the first electromagnet 411 and activates the second electromagnet 412 in in such a way that said second electromagnet 412 generates a magnetic field such as to attract said second permanent magnet 42 and, therefore, such as to cause the turbine 32 to continue to rotate anti-clockwise around the central axis 0.

Furthermore, when on the basis of the electrical signal received from the Hall effect sensor 413, the electronic control unit 414 determines that the first permanent magnet 42 and the second permanent magnet 42, thanks to the rotation of the turbine 32 around the central axis 0, arrived in front, respectively, of the first electromagnet 411 and the second electromagnet 412, said electronic control unit 414 turns off the second electromagnet 412 and activates the first electromagnet 411 again in such a way that said first electromagnet 411 generates a magnetic field such as to reject said first permanent magnet 42 and, therefore, such as to cause the turbine 32 to continue to rotate anti-clockwise around the central axis 0.

Ultimately, in use, the electronic control unit 414 alternately drives the first 411 and the second electromagnet 412 in such a way as to cause a continuous rotation of the wind turbine 32 around the central axis 0.

Alternatively, as will be evident to a person skilled in the art also in the light of the preceding discussion, the electronic control unit 414 can operate the first 411 and the second electromagnet 412 in pairs, or jointly, in order to obtain the aforesaid continuous rotation of the wind turbine 32 due to the effect of the magnetic alternation between electromagnets and magnets.

The electrical power supply to the control module 41 can be provided by the electrical network and / or by a direct current power supply device, for example a battery, and / or by a photovoltaic system configured to generate electrical energy by means of one or more photovoltaic panels .

It is important to underline the fact that various modifications can be made to the previously described operation of the control module 41 and to the structure of said control module 41 shown in Figure 4 and previously described, however, leaving unchanged the operating principle of the wind turbine 32 based on the magnetic interaction between said control module 41 and the magnetic means. For example, the first electromagnet 411, the second electromagnet 412 and the Hall effect sensor 413 could be conveniently arranged along an arc of a circumference lying on a plane perpendicular to the central axis 0 and which is centered on said central axis 0 in so that:

• the rope which joins the centers of the first electromagnet 411 and of the second electromagnet 412 has a length equal to a multiple or a submultiple of the aforesaid predefined length; and / or

• the Hall effect sensor 413 is adjacent, along said arc of circumference, to the second electromagnet 412; and / or

• the rope that joins the centers of the Hall effect sensor 413 and of the first / second electromagnet 411/412 has a length equal to a multiple or a submultiple of the aforesaid predefined length.

Moreover, the control module 41 could be conveniently configured for:

• cause a clockwise rotation of the magnetic means and, therefore, of the wind turbine 32 around the central axis 0; and / or

• operate the electromagnets 411 and 412 in such a way as to generate only magnetic fields such as to reject the magnetic means or only magnetic fields such as to attract the magnetic means.

Furthermore, with regard to the possible modifications that can be made to the electric motor previously described, figure 6 shows a motorized wind turbine aspirator made in accordance with a second preferred embodiment of the present invention.

In particular, with the exception of the electric motor with which the aspirator is equipped in accordance with the second preferred embodiment of the present invention and which will be described in detail below, said aspirator comprises a basic structure and a wind turbine which are structured and configured as, respectively, the base structure 31 and the wind turbine 32 of the aspirator 30 and which, therefore, will not be described again.

In detail, figure 6 shows a cross section of the end portion of the wind turbine of said aspirator in accordance with the second preferred embodiment of the present invention in a plane which is perpendicular to the central axis of said wind turbine.

In detail, as shown in Figure 6, the end portion (indicated here with 60) of the wind turbine of said aspirator in accordance with the second preferred embodiment of the present invention is coupled, by means of radial arms 61, to a shaft 62 in such a way as to be rotatable about said shaft 62.

Furthermore, Figure 6 also shows:

• a ferrite ring 63 which

is fixed to the collar (for simplicity not shown) of the basic structure of the aspirator in such a way as to surround the end portion 60 of the wind turbine and to be centered with respect to the shaft 62, and includes magnetized sectors and non-magnetized sectors, each magnetized sector being comprised between two non-magnetized sectors, the magnetized sectors being arranged along said ferrite ring 63 in such a way that each string which joins the centers of two adjacent magnetized sectors along said ferrite ring 63 has the same predetermined length;

• a first electromagnet 64 and a second electromagnet 65 which are fixed on an internal surface of the side wall of the end portion 60 of the wind turbine in such a way that the distance between the centers of said electromagnets 64 and 65 is equal to the aforementioned predefined length or to a multiple preset or a submultiple preset of the aforementioned predefined length;

• a Hall effect sensor 66 which is fixed on the internal surface of the side wall of the end portion 60 of the wind turbine in such a way that the distance between the centers of said Hall effect sensor 66 and of one of the two electromagnets 64 or 65 is equal to a predefined multiple of the aforesaid predefined length, said Hall effect sensor 66 being configured to measure the intensity of a surrounding magnetic field, in particular the intensity of the magnetic field generated by the magnetized sectors of the ferrite ring 63;

• an electronic control unit 67 which is connected to the Hall effect sensor 66 and to the two electromagnets 64 and 65, and is for example housed inside the shaft 62, being configured for

receiving from the Hall effect sensor 66 an electrical signal indicative of the magnetic field strength measured by said sensor 66,

determining, on the basis of the electrical signal received from the Hall effect sensor 66, a relative position of the Hall effect sensor 66 and of the electromagnets 64 and 65 with respect to the magnetized sectors of the ferrite ring 63, and,

on the basis of the determined positions, actuate the first electromagnet 64 and / or the second electromagnet 65 in such a way that the at least one driven electromagnet generates a magnetic field such as to repel or attract the magnetized sectors of the ferrite ring 63 and, therefore, such as to cause a rotation of the end portion 60 and, therefore, of the entire wind turbine around the shaft 62;

• a first counterweight 68 which is

fixed on the inner surface of the side wall of the end portion 60 of the wind turbine in such a way as to be arranged in a position diametrically opposite to that of the first electromagnet 64, and

configured to counterbalance the weight of the first electromagnet 64; and

• a second counterweight 69 which is

fixed on the inner surface of the side wall of the end portion 60 of the wind turbine in such a way as to be arranged in a position diametrically opposite to that of the second electromagnet 65, and

configured to counterbalance the weight of the second electromagnet 65.

Alternatively, the ferrite ring 63 could conveniently be replaced by a plurality of permanent magnets which are

• arranged around the collar of the basic structure of the aspirator (for example inside it) along a circumference which lies on a plane perpendicular to the shaft 62 and which is centered on said shaft 62 in such a way that each cord that joins the centers of two adjacent permanent magnets has the aforementioned predefined length; And

• each configured to generate a predefined magnetic field.

Also in the case of the motorized wind turbine aspirator made in accordance with said second preferred embodiment of the present invention the electric power supply can be supplied by the electric network and / or by a direct current power supply device, for example a battery, and / or by a photovoltaic system configured to produce electricity by means of one or more photovoltaic panels.

In particular, said second preferred embodiment of the present invention, since the control module of the electric motor is housed inside the wind turbine, or since the electronic control unit 67, the Hall effect sensor 66 and the first 64 and second electromagnet 65 are housed inside the wind turbine, allows you to install a photovoltaic panel directly on the wind turbine, as shown in figure 7.

In particular, in figure 7 the motorized wind turbine aspirator is indicated as a whole with 70, the base structure is indicated with 71 and the wind turbine is indicated with 72.

As shown in Figure 7, the portion of the wind turbine 72 external to the base structure 71 comprises a flat upper surface on which a photovoltaic panel 73 is installed connected to the control module of the electric motor of the aspirator 70 and configured to generate electrical energy and to supply the electrical energy generated to said control module arranged inside the wind turbine 72. Conveniently, the photovoltaic panel 73 is integrated with the wind turbine 72, and all the cables and electrical wires required for the electrical connection of the various components are housed inside the same wind turbine 72, thus allowing easy installation of the aspirator 70.

Conveniently, the photovoltaic panel 73 can also be an extra-light monocrystalline photovoltaic module encapsulated in a polymer structure such as to protect said photovoltaic panel 73, or such as to make said photovoltaic panel 73 insensitive to bad weather.

In both preferred embodiments of the present invention described above, thanks to the presence of the Hall effect sensor, the electronic control unit is able to determine the number of revolutions of the wind turbine and, therefore, is also able to decide whether or not to operate the electromagnets depending on whether or not there is sufficient wind to make the wind turbine rotate. In particular, if the wind speed guarantees a number of revolutions of the wind turbine sufficient for air exchange (in terms of estimated cubic meters of air per hour), the electronic control unit could conveniently stop running. activate the electromagnets with consequent energy savings. If, on the other hand, the wind speed drops, the electronic control unit could conveniently start operating the electromagnets again to cause the rotation of the wind turbine.

In other words, the electronic control unit 414 or 67 can also be conveniently configured for:

• determine the number of complete rotations (or 360 °) of the wind turbine 32 or 72 during a period of time having a predefined duration and in which the electronic control unit 414 or 67 does not operate the electromagnets 411 and 412 or 64 and 65 based on the electrical signals received from the Hall effect sensor 413 or 66 and indicative of the magnetic field strengths measured by said sensor 413 or 66 during said period of time;

• if the number of complete rotations of the wind turbine 32 or 72 is greater than a first predetermined threshold, do not activate the electromagnets 411 and 412 or 64 and 65; while,

• if the number of complete rotations of the wind turbine 32 or 72 is less than a second predetermined threshold (said second predetermined threshold may be equal to the first predetermined threshold, or different from the latter in such a way as to create a sort of hysteresis mechanism ), operate the electromagnets 411 and 412 or 64 and 65 so that the wind turbine 32 or 72 rotate faster.

From the foregoing description the advantages of the present invention can be immediately understood.

In particular, the present invention has the following technical advantages:

• the motorized wind turbine aspirator according to the present invention has the same overall dimensions and modifies the aesthetics of the buildings on which it is installed in the same way as the non-motorized wind turbine aspirators; therefore the aspirator according to the present invention, unlike the motorized wind turbine aspirators of the known type, can also be installed on buildings subjected to particular architectural / aesthetic constraints;

• the aspirator according to the present invention has a very low additional cost with respect to non-motorized wind turbine aspirators and a much lower cost than that of the known type of motorized wind turbine aspirators;

• the aspirator according to the present invention does not require any maintenance linked to the wear of the electric motor; And

• the electric motor according to the present invention can be installed on wind turbine aspirators of any diameter.

Furthermore, the use of the electric motor made according to the first preferred embodiment of the present invention is particularly advantageous for sucking in hot fumes, for example from fireplaces, furnaces, etc. In fact, this electric motor is not affected in any way by the high temperatures generated by these smoke.

The use of the aspirator in accordance with the second preferred embodiment is particularly advantageous since it requires an extremely simplified installation and in particular does not require complex external electrical connections.

Finally, it is clear that various modifications can be made to the present invention, all falling within the scope of protection of the invention defined in the attached claims.

Claims (12)

CLAIMS 1. Suction device (30.70) comprising: • a basic structure (31,71); • a wind turbine (32,72) configured and coupled to the base structure (31,71) in such a way as to be rotatable, and designed to, when rotatively operated, suck air through the base structure (31,71); and • an electric motor configured to rotate the wind turbine (32,72); characterized in that the electric motor includes: • magnetic means fixed to one of the base structure (31.71) and the wind turbine (32.72); and • a control module fixed to the other between the base structure (31,71) and the wind turbine (32,72) and configured to interact magnetically with the magnetic means to cause in this way the rotation of the wind turbine (32, 72). 2. A suction device according to claim 1, wherein said magnetic means are configured to generate first magnetic fields; and said control module is configured to generate second magnetic fields such as to repel or attract the magnetic means thus causing rotation of the wind turbine (32,72) with respect to the base structure (31,71). Suction device according to claim 1 or 2, wherein the control module comprises: • a Hall effect sensor (413.66) configured to measure the intensity of a surrounding magnetic field; • a plurality of electromagnets (411.412; 64.65); and • an electronic control unit (414,67) connected to the Hall effect sensor (413,66) and to the electromagnets (411,412; 64,65) and configured to receive an electrical signal from the Hall effect sensor (413,66) indicative of the magnetic field strength measured by said Hall effect sensor (413.66), determine, on the basis of the electrical signal received from the Hall effect sensor (413,66), a position of the electromagnets (411,412; 64,65) with respect to the magnetic means, and to operate, on the basis of the determined position, the electromagnets (411,412; 64 , 65) in such a way that they interact magnetically with said magnetic means. Suction device according to claim 3, wherein the electronic control unit (414,67) is further configured for: • determine an indicative quantity of the rotation speed of the wind turbine (32.72) during a period of time in which said electronic control unit (414.67) does not operate the electromagnets (411.412; 64.65) on the basis of the electrical signals received from the Hall effect sensor (413.66) and indicative of the magnetic field strengths measured by said Hall effect sensor (413.66) during said period of time; and • start operating the electromagnets (411,412; 64,65) if the determined quantity satisfies a predefined condition. Suction device according to any one of the preceding claims, wherein the magnetic means comprise a plurality of permanent magnets (42) each of which is configured to generate a predefined magnetic field. Suction device according to any one of claims 1-4, wherein the magnetic means comprise a ferrite ring (50,63) which includes magnetized sectors (51) and non-magnetized sectors (52), each magnetized sector (51) being between two non-magnetized sectors (52). Suction device according to any one of the preceding claims, in which the magnetic means are fixed to the wind turbine (32), and in which the control module (41) is fixed to the base structure (31). A suction device according to claim 7, wherein the base structure (31) includes a collar portion (312) having an opening; wherein the wind turbine (32) includes an end portion (321) which extends within the base structure (31) through the opening of the collar portion (312); and wherein the magnetic means are fixed around the end portion (321) of the turbine (32) and are configured to generate first magnetic fields in predefined positions around said end portion (321); and wherein the control module (41) is attached to the collar portion (312) of the base structure (31). Suction device according to any one of claims 1-6, in which the magnetic means are fixed to the base structure (71), and in which the control module (67) is fixed to the wind turbine (72). A suction device according to claim 9, wherein the base structure (71) includes a collar portion having an opening; wherein the wind turbine (72) includes an end portion (60) which extends into the base structure (71) through the opening of the collar portion; and in which the magnetic means are fixed to the collar portion of the base structure (71) so as to be arranged around the end portion (60) of the wind turbine (72) and are configured to generate first magnetic fields in predefined positions around said end portion (60) of the wind turbine (72); and wherein the control module is attached to the wind turbine (72) internally with respect thereto. Suction device according to claim 9 or 10, further comprising a photovoltaic panel (73) fixed to the wind turbine (72), connected to the control module (67) of the electric motor and configured to generate electrical energy and to supply energy electricity generated at said control module. Suction device according to any one of the preceding claims, wherein said base structure (31,71) is configured so as to be coupled to an exhaust duct or to a flue or to an aeration mouth; and in which said wind turbine (32,72) includes an intake structure with blades, operable to draw air from said exhaust duct or flue or aeration mouth.