The disclosure relates to a rotor assembly having a fan wheel as well as to a radial fan having such a rotor assembly.
With certain applications of radial fans, there is the basic problem that a seal is required between the rotor and the stator or the electronics system so that a fluid cannot reach the stator or the electronics housing.
There are already solutions for slowly running pumps, in which they are driven from the exterior by a magnetic mating coupling, via a magnetic coupling plate, through a separating can housing. This magnetic mating coupling is flanged-mounted, for example, directly or separately and driven by an electric motor.
This design comprises many components and requires a comparatively large installation space due to the magnetic coupling. With the high rotational speeds of a radial fan, a compact unit with a high power density accordingly cannot feasibly be realized with a separate magnetic coupling.
Sealing of the electronics area without a separating can with the aid of abrasive shaft seal rings generates undesirable friction and rapid wear. The high rotational speeds are also a limiting factor here.
High-speed applications within the meaning of the present disclosure are rotational speeds of the fan wheel in which the circumferential speed at the outlet of the radial compressor is at least 60 m/s.
In this regard, the known solutions from the area of comparatively slowly rotating separating can pumps cannot be applied to high-speed fans when using canned motors.
Furthermore, the classic design requires a separation of the bearing seats. A precisely fitted bearing alignment of the bearings and bearing seats can only be ensured, however, with extensive effort. The alignment of such a unit must take place in two steps due to the bearings on both sides. First, the anchor must be balanced in a first step; subsequently, the entire unit must be balanced because the anchor is inaccessible.
In the event that access will be made to a split or multi-part housing for a fluid seal or, for example, to a separating can open on one side, there is always still the problem of the seal between the stator and the rotor after installation of the rotor unit. Thus, the rotor unit can initially be completely assembled, for example, when the bearing tube is attached, for example, as an injection-molded component in the primary housing. However, in this case it is necessary that the separating can is designed to be open from the rear, and thus it must be closed and sealed off after completion of all assembly steps.
Aspects of example embodiments overcome the aforementioned disadvantages and provide a rotor assembly of a radial fan, particularly of a high-speed radial fan, which provides an optimized assembly option and with which a seal can simultaneously be obtained between the rotor and the stator while simultaneously having good efficiency.
These aspects of example embodiments are achieved by the combination of features according to claim 1, for example.
According to an example embodiment, a rotor assembly for a high-speed radial fan is proposed for this, comprising a bearing tube which is axially open in the interior and in which a shaft carrying a fan wheel is mounted with a rotor, in which the rotor of the rotor assembly is mounted in a cylindrical separating can of a housing.
A further aspect of the an example embodiment relates to a radial fan having a fan housing, which is formed as a single piece with the separating can and, accordingly, the rotor assembly is housed in the separating can of the fan housing.
In one advantageous example embodiment of the disclosure, it is provided in this case that the bearing tube with the shaft and the rotor mounted on the shaft is arranged in the separating can, which is closed around the circumference.
In one preferred embodiment, a design is provided, in which the separating can extends away from a substantially flat housing base plate of the fan housing in the axial direction. It is likewise advantageous if an air gap is formed between the rotor and a stator surrounding the rotor (50), and the separating can with its cylindrical separating can walls is arranged within the air gap. In this manner, a drive of the fan shaft can be realized without the necessity of a magnetic coupling.
It is further preferred when the material of the separating can is not a good electrical conductor, because this leads to eddy-current losses due to the rotating magnets. The contact resistance of the separating can material should not be below 10 Ohm. A magnetic permeability of the separating can material should likewise be close to 1, because, otherwise, parts of the magnetic field become shielded.
In a likewise advantageous embodiment of the disclosure, it is provided that the shaft, on a first bearing arranged in the bearing tube and a second bearing arranged in the bearing tube spaced apart in the axial direction as relates to the first, are mounted centrally in a region between the fan wheel and the rotor.
The topology of the motor is optimized accordingly for high speeds. In order to reduce the speed of the electrical field, the rotor has the minimum number of pole pairs of 1 or 2 poles. It is thereby possible to accommodate a large magnetic air gap without having to accept excessively large losses in efficiency in this case. The separating can which separates the rotor region from the stator region can be placed in this magnetic air gap. In one advantageous embodiment of the disclosure, it is accordingly provided that the rotor of the motor has precisely 2 or 4 poles.
In a further advantageous embodiment of the disclosure, it is provided that the stator is surrounded by a housing, which provides a receiving compartment for the stator and preferably motor electronics installed in the receiving compartment, in which the housing is sealed off to the fan housing and is connected thereto.
To make assembly easier, the bearing tube with a radial overhang rests upon a housing base plate of the fan housing and is connected to the fan housing by means of a connection assembly, in which the overhang extends, at least partially, over the outer circumference of the fan wheel.
The advantages of the example embodiments can therefore be summarized as follows:
The design can be adapted further at various operating points due to the various scaling options. Such scaling options include, for example, the fan diameter, the fan rotational speed, the fan shape, the height of the fan blade, the cross-section of the spiral housing, the diameter of the connecting pieces, the size of the ball bearings, the active length of the motor, the diameter of the stator, the diameter of the magnet, the size of the air gap, the construction of the circuit board, the winding configuration, and the shaft diameter.
Other advantageous further embodiments of the disclosure are characterized in the dependent claims and/or are shown in more detail in the following by means of the figures, along with the description of the example embodiments of the disclosure. The following is shown:
The example embodiments of the disclosure is described in more detail in the following with reference to
The rotor assembly 10 comprises a bearing tube 20 which is open axially in the interior. A shaft 40 is mounted in the bearing tube 20, in which a rotor 50 of a canned motor is mounted on the shaft 40. An air gap is formed between the rotor 50 and a stator 51 surrounding the rotor 50, and the separating can with its cylindrical separating can walls 3a is arranged within the air gap. The motor stator 51, which is external in this respect, is then arranged in a housing 52. In this exemplary embodiment, the rotor 50 has precisely 2 poles.
The housing 52 forms a receiving compartment for the stator 51 and the motor electronics 55, in which the housing 52 is sealed off at sealing surfaces 56 as relates to the fan housing 2 and is connected thereto.
The bearing tube 20 has an overhang 21 which protrudes outwardly radially.
The sectional view according to
The overhang 21 further has a collar 23, which extends outwardly circumferentially and protrudes upwardly, and which extends in the axial direction A and surrounds the radial edge region 32 of the fan wheel 30 radially outwardly. In other words, the fan wheel 30 is placed on the shaft 40 such that the fan wheel 30 is arranged in the overhang 21 in the recess.
The shaft 40 is mounted between two bearings 24, 25, in which a spring 28 is preloaded against the first bearing 24, which is supported on an inner bar 29. The second (lower bearing 25 in
The separating can 3 of the housing 2 extends away from a substantially flat housing base plate 2a of the fan housing 2 in the axial direction. The bearing tube 20 is mounted with its radial overhang 21 on the housing base plate 2a and is connected to the fan housing 2 by means of a screw connection.
The claimed invention is not limited in its design to the aforementioned example embodiments. Rather, a number of variants is conceivable, which would make use of the solution shown even with essentially different designs. Thus, the design of correspondingly application-specific scaling options could be adapted to the application, as previously explained.
Number | Date | Country | Kind |
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10 2018 129 612.6 | Nov 2018 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2019/078558 | 10/21/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/104127 | 5/28/2020 | WO | A |
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Entry |
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Number | Date | Country | |
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20220003237 A1 | Jan 2022 | US |