This disclosure generally relates to a centrifugal fan, and more particularly relates to cooling passageways or slots arranged about the hub of the fan to allow cooling air to pass through the motor driving the fan without producing excessive noise.
Electric motors used to power blowers in Automotive Heating, Ventilation, and Air Conditioning (HVAC) systems benefit from cooling air flow directed through the motor itself. It is known to provide circular holes in the dome or hub portion of a centrifugal fan to allow cooling air to pass through the electric motor driving the fan. This cooling air flows internally through the motor to remove heat generated by brushes, coils, and/or electronic control elements so that the motor runs efficiently and with reduced degradation. However, circular holes often create a noise which has a frequency related to the number of holes as they pass a high pressure area developed at the inlet area of the fan. The noise can propagate through the HVAC system as noise heard by a person such as a passenger in an automobile. It is therefore desirable to have openings in the fan for cooling the motor that do not cause noise.
In accordance with one embodiment, a centrifugal fan suitable for use in a vehicle heating, ventilation, and air conditioning (HVAC) system is provided. The fan includes a hub, a plurality of fan blades, and a plurality of passageways. The hub is configured to define an opening suitable to receive a shaft of a motor. The plurality of fan blades is arranged about a perimeter of the hub. The plurality of passageways is arranged about the hub between the opening and the perimeter to allow air to pass through the motor. The passageways are configured to minimize noise caused by the air drawn through the motor.
In another embodiment, a blower assembly suitable for use in a vehicle heating, ventilation, and air conditioning (HVAC) system is provided. The assembly includes a motor and a fan. The motor is configured to define an exit region where air that flows through the motor exits the motor. The centrifugal fan is configured to attach to a shaft of the motor. The fan defines a plurality of passageways configured to allow the air from the motor to pass through the fan. The passageways are configured to minimize noise caused by the air drawn through the motor.
Further features and advantages will appear more clearly on a reading of the following detailed description of the preferred embodiment, which is given by way of non-limiting example only and with reference to the accompanying drawings.
The present invention will now be described, by way of example with reference to the accompanying drawings, in which:
The motor 12 is generally configured to define an exit region 20 where air 22 that flows through the motor 12 exits the motor 12. It is advantageous for the air 22 to flow through the motor 12 to cool various parts of the motor 12 such as bushings and bearings. Lower operating temperatures of these and other parts of the motor 12 generally extends the operating life of the motor 12. While the exit region 20 is illustrated as a circular hole, and the arrangement of the plurality of circular holes illustrated may also be part also part of the exit region 20, it is recognized that other configurations of exit regions with different shaped holes are possible.
The fan 14 also includes a plurality of passageways 32 arranged about the hub 24 between the opening 18 and the perimeter 28 to allow the air 22 that passed through the motor 12 to also pass through the fan 14. A prior attempt to provide for the passage of cooling air from a motor through a centrifugal type fan used a plurality of circular holes arranged about the hub of the fan. The circular holes were all located at the same distance or radius from the center of the hub. It was observed that the plurality of circular holes generated an undesirable amount of noise when passing cooling air from a motor similar to that shown in
In order to reduce the noise, the passageways 32 describe herein are configured to minimize noise caused by the air 22 drawn through the motor 12. That is, the passageways are configured to minimize the variation in pressure caused by the passing of the passageways 32 over the exit region 20. Again, while not subscribing to any particular theory, it is believed that the passageways 32 should generally be configured so there is always some portion of at least one of the passageways overlying any portion of the exit region 20. As such, the fan 14 defines a plurality of passageways 32 configured to allow the air 22 from the motor 12 to pass through the fan 14, where the passageways 32 are configured to minimize noise caused by the air 22 drawn through the motor 12.
By way of further explanation, if a radial vector or radial line 34 is drawn that originates at a center 36 of the hub 24 and is held stationary as the fan 14 rotates underneath it, the arrangement of the passageways 32 is such that there is always a slot under the radial line 34. As one passageway is exiting or passing by the radial line 34, the next or adjacent passageway is already under radial line 34. This is intended to prevent a break in the flow of the air 22.
Continuing to refer to
In this non-limiting example, each slot may be characterized as curved. A curved shape is believed to be advantageous over a relatively strait slot because curved slots allow the desired length of slot to be provided within a shorter diametrical zone of the fan hub. The fan hub topography is somewhat like a hill which is steeper further from its peak. So a molding detail to create the slot width will create an open area closer to the planar or projected shape where the topography is less steep.
In some instances, balance clips (not shown, little metal spring clips that press onto the fan blade) may be added at the appropriate location to balance the fan 14. In order to prevent a dropped clip from falling through the slot and into the motor 12, the width of the slot may be selected to be less than the minimum dimension of a balance clip.
As mentioned above, the passageways 32 may be arranged such that at least one passageway intersects any radial line originated at the hub. Instead of aligning a leading edge of one passageway with a trailing edge of a passageway, it was discovered through empirical testing that noise could be further reduced if adjacent passageways are arranged to overlap the radial line 34 as illustrated. The optimum amount of overlap generally depends on the pressure difference on the opposing sides of the hub 24, the amount of restriction of the HVAC system, and the shape of the passageways 32. In most instances where the passageways 32 are slots, some overlap provides for the least noise, but some fan configurations may tolerate zero overlap where one slot starts at the same radial line as one ends. In general, a combination of testing and computer modeling is used to optimize the amount of overlap.
The number of the passageways 32 may be varied, and depending on the design of the motor 12, it may be advantageous if the number is a prime number. For example, if the fan 14 has twelve passageways or slots, and the fan 14 rotates at 1000 revolutions per minute (RPM), the frequency generated would be 12 slots/rev*1000 Rev/min*1 min/60 sec=200 Hz. 200 Hz would be the base frequency. But 12 is divisible by 2, 3, 4 & 6 so there could be noise at harmonic frequencies of 33 Hz, 50 Hz, 67 Hz, & 100 Hz respectively. There can also be multiples of the base frequencies and its sub-harmonics as well. As such, the noise may include frequencies that could excite cavity resonances or structural resonance in the HVAC system that could amplify the noise. With a prime number of slots, e.g. 13, the base frequency is 216 Hz for rotation at 1000 RPM, and the next harmonic is double that at 432 Hz.
While the spacing of the passageways 32 (i.e. slots) is illustrated as being relatively uniform, it is recognized that there may be some benefit realized by randomizing the spacing of the slots as well as widths. A disadvantage of doing so can be that balancing the fan 14 by adding balancing clips may be more complicated and time consuming. It is noted that prior to conceiving the idea of overlapping the slots, several options of irregular shaped passageways and irregularly spaced holes were tested, without substantive success. For the configuration of the motor 12 illustrates, the best test results were realized by the overlapping curved slots illustrated in
Accordingly, a blower assembly (the assembly 10) and a fan 14 are provided. In general, increased noise is created by the alternating open-close or solid-open sections as they pass through a high pressure region proximate to the hub 24, thus creating peak pressure fluctuation. In order to provide cooling with minimum noise, the assembly 10 and the fan 14 described herein attempts to provide a relatively continuous opening relative to the passage through the high pressure area while at the same time maintaining structural connections between the fan blades and the shaft 16 of the motor 12. This is achieved by creating slots that are angled such that they are contiguous or slightly overlapping while creating a structural web connecting the upper and lower portion of the fan as shown in
While this invention has been described in terms of the preferred embodiments thereof, it is not intended to be so limited, but rather only to the extent set forth in the claims that follow.
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