NL9402191A - Fan. - Google Patents

Description

The invention relates to a fan, comprising: a central hub; a number of blades connected to said hub, which extend at least more or less in the radial direction, which blades have such a shape that air movement occurs around the axis of the hub when the drive is rotary; and drive means for rotatingly driving the blades with the hub about the axis of the hub.

Such a fan is known. It is designed such that the drive means comprise a motor of non-negligible diameter, the output shaft of which motor is directly connected to the hub. The hub has a diameter, which is also negligible, adapted to the diameter of the motor.

The drawback of such a known structure is that the central part of the fan does not cooperate in generating the desired airflow, which is undesirable for reasons of efficiency.

A further important efficiency limiting aspect is the circulation of the ends of the blades, the so-called tips.

It would be desirable to eliminate this tip flow.

Another drawback of the known fan is that the motor shaft and the hub are directly and rigidly coupled to each other. Due to this unbreakable coupling, known fan lacks any flexibility in choosing the type of motor and the motor design is completely determined by the desired speed.

It is therefore an object of the invention to design a fan in such a way that losses due to the presence of an aerodynamically inactive hub are reduced to negligible proportions.

A further object of the invention is to design a fan in such a way that greater flexibility is obtained with regard to the choice of the or each drive motor, whereby the transmission between the rotor, including hub and the blades, and the motor can be designed to rotate both the rotor and the motor at the best possible speed.

To achieve this object, the invention provides a fan of the type mentioned, which is characterized in that the end zones of the blades are connected by a ring, which ring is rotatably mounted in a housing; and the drive means comprises a motor spaced from the hub outside of the airflow generated by the driven blades.

A specific embodiment is that in which the ring forms part of the drive means.

For example, this variant can have the special feature that the ring is driven by a motor.

A specific embodiment has the special feature that the ring is the rotor of a possibly collectorless electric motor.

A variant of the latter embodiment has the special feature that the rotor is a linear induction motor.

Mechanical rotary alloy can be used. In an alternative, the fan according to the invention has the special feature that the rotor is suspended magnetically during operation.

A further increase in efficiency is obtained with an embodiment in which the blades have an aerodynamic shape with maximized ct / cD at a minimized (cD) 0, being the molding resistance at cL = 0.

A light and nevertheless mechanically very strong embodiment has the special feature that the blades are connected to the hub and the ring under pretension.

Yet a further variant with a very light rotor has the special feature that the blades each comprise a skin consisting of metal with a thickness of at most 1 mm.

A particular embodiment has the special feature that the blades each comprise a skin consisting of a plastic layer reinforced with tensile fibers.

The aforementioned two embodiments can be characterized in that the skin has a thickness of 0.001-0.03 x the average chord of a leaf.

Particularly when using pretension, the latter variant can make use of a very thin skin. For example, the fan can then have the special feature that the skin has a thickness of (0.2 ± 0.1) mm.

Various suitable materials are eligible. For reasons of strength on the one hand and price on the other, the embodiment is preferred, in which the skin consists of aluminum or stainless steel.

To obtain increased resistance to impact deformation or the like, the fan may have the special feature that the skin enclosed cavity is filled with a filler.

The latter embodiment can be manufactured in a simple manner. This variant has the special feature that the filler is pre-modeled in a mold cavity and then the skin is applied around it.

Yet a further increase in efficiency can be obtained with an embodiment in which the number of blades exceeds four. For example, the number of blades can be eight or more. When an aerodynamically optimized design is used, the efficiency compared to known fans can be very high, while the speed tolerance range is further extended. For example, the average thickness of the blades may be on the order of 15% of the cords. In known designs, this thickness is of the order of 2 to 3%. With such a design, the drag coefficient cD decreases, while the lift coefficient cL can be increased from 0.8 to 1.6, for example. The efficiency of the fan is related to the quotient cL / cD. Due to these measures, the fan efficiency can hereby be increased to the order of 90%. In known designs, this efficiency is of the order of magnitude of up to 50%. Decreasing (cD) 0 also contributes to a reduction in the sound emitted.

An advantage of using a larger number of blades is that the applied speed can be lower and the noise production can correspondingly decrease.

The blades will taper towards their ring-turned ends for optimized aerodynamic design. The torsion of the blades, viewed in the axial direction of the fan, may have a torsion of the order of 15 ° at the centerline, while the blades at the tips, i.e. the ends adjacent to the ring, for example, a torsion in can exhibit the order of 65 °.

In order to conduct the air flow generated by the fan as well as possible, the fan can have the special feature that at least the inner surface of the ring has an aerodynamic shape.

The version in which the end zones of the blades smoothly adjoin the inner surface of the ring is limiting noise and increasing efficiency.

This embodiment can advantageously have the feature that the end zones have a circumferentially widening shape with a radius of curvature in the same order of magnitude as the characteristic thickness of the blades.

A variant in which the blades have an aerodynamic shape with maximized cL / cD at minimized cD can advantageously also have the feature that the blades have a rear edge with a small thickness relative to the aerodynamic boundary layer during operation of the fan.

In a variant in which the blades each comprise a skin of metal or reinforced plastic, the aforementioned embodiment can have the special feature that the rear edge is formed by one skin layer, which adjoins a zone in which two skin layers overlap, the skin layer of the trailing edge is on the convex side.

The invention will now be elucidated with reference to the annexed drawings. Herein: figure 1 shows a partly broken away perspective view of a fan according to the invention in a first exemplary embodiment; figure 2 shows a partly broken away perspective view of a second exemplary embodiment; figure 3 shows a partly broken away perspective view of a third exemplary embodiment; figure 4 shows a longitudinal section through a fourth exemplary embodiment; and figure 5 shows a partly broken away partial perspective view of a part of the fan.

Figure 1 shows a fan 1, comprising a central hub 2, eight blades 3 connected to said hub 2, which extend at least more or less in the radial direction and have such a shape that, when rotating drive around the axis of the hub 2, a air displacement occurs. The end zones 4 of the blades 3 are connected to each other by a ring 5, which is carried rotatably and drivably in a housing 6.

A motor 7 serves to drive the rotor 2,3,4,5, which drives a drive roller 9 via a transmission 8. This in turn drives the ring 5 by frictional contact. It is further supported by two free guide rollers 10,11, which are resiliently received from and to the ring 5 in the housing 6.

The inner surface 12 of the ring 5 has a rounded aerodynamic shape.

Figure 2 shows a fan 12, the housing 13 of which is adapted to accommodate two rotors 2,3,4,5. The motor 7 drives both rotors. For this purpose use is made of a toothed belt 15 driven by a gear 7 driven by the motor 7, which co-acts with a pinion 16 arranged around each ring 5. Two freely rotating gears 17, 18 are mounted fixedly with respect to the housing 13 and serve for the correct positioning of the two rotors 2, 3, 4, 5, in combination with the tensile stress in the toothed belt 15. Space has been saved by using two freely rotating deflector rollers 19,20, so that the toothed belt is on both the top and bottom of the rotors engage in a substantially horizontal direction.

Figure 3 shows a fan 21, the housing 22 of which is rotatably supported by frame 23. The housing 22 is of tubular design and has an aerodynamic shape on its inner surface 24. A rotor 2,3,4,5 is attached to that inner surface 24. It is noted that the ring 15 may be used for production purposes. It could also be omitted, namely in the case where the blades 3 are directly connected to the inner surface 24, for example under prestress.

Electric energy is supplied via schematically indicated electrical connections 25, 26 to a stator winding 27, which forms part of the frame 23. The housing 22, which, as stated, is rotatable relative to the frame 23, carries a ring 28 of magnetic means, which together with the stator winding 27 form a collectorless electric motor. If desired, this motor can be designed such that the housing 22 is electrically suspended during operation.

Figure 4 shows a fan 29 with a plastic housing 30 and a protective cap 31 of metal mesh.

The rotor 2,3,4,5 carries magnets 32, which cooperate with a stator winding 33, analogous to the embodiment according to figure 3.

The blades 3 comprise a foam core 34, for example of plastic, such as PUR, with stainless steel skin plates with a thickness of the order of 0.2 mm. In order to obtain a sufficiently great mechanical strength and rigidity, the wall of the housing 30 comprises a number of metal bars 36 glued therewith.

In the region of the rotor 2-5, the inner surface of the housing 30 has a streamlined shape, as can be seen in the upper left corner of Figure 4. A foam filling 37 was used for low weight.

In an embodiment, in which the blades comprise a skin, the skin has a thickness, which is preferably associated with the span and chord of those blades.

Figure 5 shows, in partly broken away perspective view, the structure of the fan blades 3. Each blade 3 comprises an aerodynamically shaped skin 38, such that the blade 3 has a convex surface 39 and a concave surface 40. These surfaces join together via a curved front edge 41 with a relatively small radius of curvature. In the rear zone 42, the surfaces 39 and 40 overlap. Beyond the overlap zone 43 protrudes that skin part, which adjoins the convex surface 39. Thus, a protruding rear edge 44, consisting of a thin layer, corresponding to the thickness of the skin is obtained.

The blade 3 is further filled with foam 45.

In the exemplary embodiments according to Figures 1, 2 and 5, the end zones of the fan blades connect smoothly to the inner surface of the ring. These end zones have a shape that widens over their entire circumference. The radius of curvature is more or less constant and has a value of the same order of magnitude as the characteristic thickness of the fan blades.

Claims (21)

A fan, comprising: a central hub; a number of blades connected to said hub, which extend at least more or less in the radial direction, which blades have such a shape that air movement occurs around the axis of the hub during rotary driving, and driving means for rotating driving the blades with the hub around the centerline of the hub, with the marking. that the end zones of the blades are connected by a ring, which ring is rotatably mounted in a housing; and the drive means comprises a motor spaced from the hub outside of the airflow generated by the driven blades. 2. Fan as claimed in claim 1, wherein the ring forms part of the drive means. Fan according to claim 2, wherein the ring is driven by a motor. Fan as claimed in claim 2, wherein the ring is the rotor of an optionally collectorless electric motor. Fan according to claim 4, wherein the rotor is a linear induction motor. Fan as claimed in claim 4, wherein the rotor is suspended magnetically during operation. Fan according to claim 1, wherein the blades have an aerodynamic shape with a maximized cL / cD at a minimized (co) 0, being the molding resistance at cL = 0. The fan of claim 1, wherein the blades are biased to the hub and ring. The fan of claim 1, wherein the blades each comprise a metal skin. Fan as claimed in claim 1, wherein the blades each comprise a skin layer of plastic reinforced with tensile fibers. Fan according to claim 9 or 10, wherein the skin has a thickness of 0.001 - 0.03 x the average chord of a blade. Fan according to claim 9 or 10, wherein the skin has a thickness of (0.2 ± 0.1) mm. Fan according to claim 9 or 10, wherein the skin consists of aluminum or stainless steel. Fan according to claim 9 or 10, wherein the skin enclosed cavity is filled with a filler. Fan according to claim 14, wherein the filler is pre-molded in a mold cavity and then the skin is applied around it. Fan according to claim 1, wherein the number of blades is more than four. Fan according to claim 1, wherein at least the inner surface of the ring has an aerodynamic shape. Fan according to claim 17, wherein the end zones of the blades smoothly adjoin the inner surface of the ring. The fan of claim 18, wherein the end zones have a circumferentially widening shape with a radius of curvature of the same order of magnitude as the characteristic thickness of the blades. Fan according to claim 7, wherein the blades have a rear edge with a small thickness relative to the aerodynamic boundary layer during operation of the fan. Fan as claimed in claims 20 and 9 or 10, wherein the rear edge is formed by one skin layer, which adjoins a zone in which two skin layers overlap, the skin layer of the rear edge being on the convex side.