MOTOR FOR A SUCTION ASSEMBLY OF AN ENHANCED-PERFORMANCE EXTRACTOR HOOD

Abstract

A single-phase asynchronous motor (1) for a suction assembly of an extractor hood (5) comprises a stator (13) wherein a rotor is driven into rotation, a driving shaft (15) carrying a rotor (16) being integral with the latter for sucking smokes and vapors from a cooktop placed below the hood (5) and for sending them towards an output (8) of the hood, said stator (13) comprising a plurality of stator core laminations (22) provided with sixteen slots (30) containing metal electrical windings wherein current flows so as to generate a magnetic flux suitable for causing the rotation of the rotor. The stator has an outer diameter (D2) greater than 80 mm, the number of the slots (30) being sixteen, such slots having a unit surface of at least 70 mm.sup.2.

Claims

1. A single-phase asynchronous motor (1) for a suction assembly of an extractor hood (5), said motor comprising a stator (13) and a rotor that is driven into rotation, a driving shaft (15) carrying the rotor (16) that is integral therewith, the rotor being adapted to suction smoke and vapors from a cooktop placed below the hood (5) and for their delivery towards an output (8) of the hood, said stator (13) comprising a plurality of stator core laminations (22) provided with slots (30) containing electrical windings through which current flows so as to generate a magnetic flux suitable for causing the rotation of the rotor, the stator has an outer diameter (D2) greater than 80 mm, the slots (30) are sixteen in number and have at least 70 mm.sup.2 of unit surface.

2. A motor according to claim 1, wherein in correspondence with a perimetral edge (38) thereof, each said stator core lamination (22) presents seats (37) suitable for accommodating screws for fixing said stator core laminations and for allowing the mounting of the stator with caps (40).

3. The motor according to claim 2, wherein such said seats (37) open on the peripheral edge (38) of each said stator core lamination.

4. The motor according to claim 1, wherein the stator (13) has an inner diameter (D1) equal to or greater than 40 mm.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0025] For a better understanding of the present invention the following drawings are attached for merely explanatory, not limitative, purposes, wherein:

[0026] FIG. 1 transparently shows an extractor hood provided with a motor according to the invention;

[0027] FIG. 2 shows a side view of a motor according to the invention;

[0028] FIG. 3 shows a front view of the stator of the motor in FIG. 2, the rotor being omitted; and

[0029] FIGS. 4-6 show comparative diagrams relevant to the noise generated by the motor according to the invention operating at different speeds V1,V2, and V3 as compared with a similar motor according to the present status of the art.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0030] With reference to the mentioned figures, a single-phase asynchronous motor 1 according to the invention for a fan of a suction assembly is inserted within a cavity 2 of a duct 3 of a structure 4 of an extractor hood 5 suitable for being installed above a cooktop of a kitchen (not shown). Such duct 3 comprises a first aperture 7 at a first end thereof located above such cooktop and a second aperture 8 at a second end thereof which operates as an exhaust of whatever is sucked (smokes and vapors, said suction being shown by arrow F) from the cooktop towards the outside of the kitchen or in the kitchen itself. In the former case, such second aperture 8 is connected to a duct, not shown.

[0031] On the first aperture 7 there are located filtering means 10 known by themselves.

[0032] The motor 1 is inserted in and fixed to, in the example shown in FIG. 1, a container 11 of the fan which is in turn constrained, in a manner known by itself, to the structure 4 mentioned above; the motor 1 can also be directly fixed to the latter. Such motor comprises a stator 13 and a rotor internal thereto, with which there is associated an output shaft 15 on which a rotor 16 of the fan is keyed in a manner known by itself suitable for sucking the smokes and vapors mentioned above. The motor and consequently the fan are driven and controlled by a usual drive and control circuit, not shown, subjected to a control generated by a user operating on a control interface 19 (shown in FIG. 1 for explanatory purposes).

[0033] The motor according to the invention comprises a stator having an inner diameter D1 (>40 [mm]) similar to that of the known motors, but an outer diameter D2 greater than that of the latter (usually <80 [mm]). Specifically, the diameter D2 is greater than 80 mm and is preferably less than 87 mm.

[0034] In the stator core laminations 22 of such stator 13 sixteen (16) slots are present.

[0035] Thanks to their greater width, the slots can contain a higher number of windings or cables of a greater cross-section; this allows to have a higher efficiency of the motor due to the reduced losses by Joule effect, the height of the bundle of stator core laminations being equal to that of the known motors, which entails the possibility of bringing the energy efficiency class of the hood to a level higher than those which use known motors. This applies, the height of the pack of stator core laminations and of the fluid dynamics system in which the motor is installed being equal. This allows to optimize the efficiency of the fan of the hood while limiting the dimensions and the weight of its motor.

[0036] Furthermore, there is an optimization in the power consumption of the motor because electrical efficiency increases; one might devise to reduce the height of the stator pack hence of the motor in general, in order to equal the efficiency of the new motor to that of a motor currently in use, to the advantage of the possibility of using the motor in hoods featuring particularly reduced dimensions.

[0037] All of this allows to meet the most stringent standards bound to the energy efficiency class of the hood, which is impossible or very difficult to obtain with the known motors because of the impossibility of increasing the dimensions in height beyond a certain value (for its positioning in the structure 4) and above all of increasing the number of the windings in the slots and their cross section and of their stators because of the current dimensions of the slots themselves.

[0038] The stator core laminations 22 comprise apertures or peripheral seats 37 suitable for accommodating (partially, because they open on the perimetral edge 38 of every stator core lamination) screws to fix the stator pack within the stator's body. This means that such screws (not shown) do not cross the stator pack internally thereto (i.e. within every stator core lamination 22, far away from the edge 38), as in the known solutions. This allows to prevent interferences of such screws with the magnetic field generated by the stator to the full advantage of the efficiency of the latter.

[0039] Also, such screws do not interfere with the windings, because the usual caps 40 of the stator comprise seats 41 for the screws themselves outside the diameter of the stator. It is to be noted that the greater transversal dimension of the stator, the new position of the screws, and the perfect concentricity between the rotor assembly and the stator assembly, lead to a reduced noise generated by the motor according to the invention as referred to the known solutions.

[0040] As a matter of fact, the diagrams in FIGS. 4-6 show substantial reductions of the sound pressure (in the ordinate) with respect to the frequency of rotation measured at different speeds of rotation V1, V2, V3: curve A shows the noise of the known motors (the motor, diffuser, rotor fluid dynamics system being equal), whereas curve B shows the noise generated by the motor according to the invention. A reduction of the peak of sound pressure (or noise) of curve B with respect to curve A is apparent.

[0041] Thanks to the invention, it is possible to obtain a motor 1 for a fan of an extractor hood having a higher efficiency with respect to its corresponding known motors, the height of pack of stator core laminations being equal, which allows for the hood 5 wherein it is placed to be classified to a high energy efficiency class (for instance class A according to the European standards). Furthermore, the motor 1 is more compact with respect to the known ones, the power being equal, vibrates less than the latter, is not too heavy, and cools better than the known motors thanks to the increased transversal dimensions of the laminations with respect to the dimensions of the known motors, the power being equal (every lamination featuring a diameter greater than 80 mm and lower than 87 mm versus a maximum diameter of 80 mm of the laminations of such known motors).

[0042] Others embodiments of the invention can be obtained in the light of the previous description and are to be considered to fall within the scope of the following claims