EP2932104B1 - Axial fan - Google Patents

Description

The present invention relates to an axial fan with blades according to the preamble of claim 1.

There are such axial fans are known in which the blades have a flow profile. The orientation of the blades on the impeller hub is adjustable by the blades are rotatable about its longitudinal axis. The blades are mounted on spars on the impeller hub. At the spars of the blades a bevel pinion is arranged in each case. The bevel pinions engage in a bevel gear which can be driven via an adjusting drive shaft.

This is the state of the art on the FR-PS 772,115 directed. There is described an arrangement for a propeller aircraft in which the blades of the propeller are rotatable about the longitudinal axis in the sense described. As a result, the conveying direction of the air when turning the propeller should be adjustable. It is described that during a rotation of the blades of the propeller about the longitudinal axis of the propeller in the sense of deceleration of the aircraft can be operated or that with a corresponding rotation of the blades of the propeller about its longitudinal axis by the propeller drive, the aircraft can drive backwards.

In the U.S. Patent 4,061,440 a fan is described in which the blades of the fan wheel should also be adjustable by rotation about its longitudinal axis, that the fan can promote in two opposite directions, depending on the position of the blades of the fan wheel. It is further described that the adjusting drive shaft can be driven by means of a hydraulic motor.

The same shows the U.S. Patent 3,054,458 ,

In the EP 0 967 104 A2 Also, a fan motor is described which is used for supplying cooling air to a heat exchanger of an engine. This fan motor has one Speed, which is generally directly dependent on the speed of the motor. Since the engine can operate at the same speed but with different load, also varies according to the amount of heat that must be dissipated by the heat exchanger at the same engine speed. Accordingly, there is a need to be able to adjust the delivery rate of the fan motor at the same speed different. This is done by the blades of the fan are rotatable about its longitudinal axis. By rotating the blades about their longitudinal axis, the efficiency of the fan and thus the flow rate can be influenced.

The present invention is based on the object to propose a construction of an axial fan, with the adjustability of the blades as simple as possible is feasible.

According to the present invention, the bevel gear can be arranged with a planetary gear on the Verstellantriebswelle. The design also proves to be advantageous if no planetary gear is used for the adjustment of the rotor blades. The bevel gear can also be arranged directly on the adjustment drive shaft.

In addition, the bevel gear is moved or held in its position.

The adjusting drive shaft is the output shaft of the adjusting motor, via which the orientation of the blades is adjusted. To distinguish this is the drive shaft of the drive motor, via which the axial fan is rotated.

It proves to be advantageous that the adjustment of the blades takes place synchronized. This results in an advantageous manner a uniform flow pattern.

Due to the construction, the blades can be rotated in particular by large angles. It is by design possible to turn the blades completely 360 degrees about their longitudinal axis adjustable. Of course, smaller angles can also be set.

This makes it possible, for example, to achieve a reversing operation of the axial fan with optimized efficiency and optimized performance for both (opposite) conveying directions (forward and reverse operation).

For this asymmetric and profiled blades are advantageously used.

This design can be used for controllable fans with blade adjustment during operation, or for fans with two positions of the blades - one for forward operation and one for reverse operation.

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  Bewetterung von Gruben und bei Schlagwetter
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  Axiale Tunnelventilatoren zur Be- und Entlüftung von Tunneln mit einer geeigneten Förderrichtung für den Brandfall
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  Strahlventilatoren mit je einem Betriebspunkt für Vorwärtsbetrieb und Reversierbetrieb bei Tunnel mit Gegenverkehr und entsprechende Schaltung bei Tunnelbrand.

When switching between forward operation and reversing operation, the fans must react quickly in the event of incidents such as the occurrence of fire, drizzle and explosion and switch to reversing operation in order to save human lives. This applies in particular to:

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  Ventilation of pits and during storm weather
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  Axial tunnel fans for ventilation of tunnels with a suitable direction of transport in case of fire
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  Jet fans, each with one operating point for forward operation and reversing operation in tunnels with oncoming traffic and corresponding circuit in tunnel fire.

According to the present invention, the impeller hub has an inner chamber. In this inner chamber an oil filling is present. The impeller hub further includes an outer chamber. The inner chamber and the outer chamber are connected via a plurality of openings, each having a sealing system which allows a portion of the oil to pass and retains a portion of the oil. Through these sealing systems, the bearings of the spars of the blades are lubricated at least during operation of the axial fan. The outer chamber communicates with the inner chamber of the impeller hub at the radially inner end region by overflow pipes, through which, when the axial fan is turned off, the oil at least partially flows back into the inner chamber of the impeller hub.

Advantageously, the peripheral bearing of the spars of the blades and the adjusting gear are lubricated by this configuration. The impeller hub is provided with an oil filling. When operating the rotor, the oil is evenly distributed.

Furthermore, the inner chamber of the impeller hub formed by the Schaufelverstelleinrichtug is sealed against the outer chamber, which is formed by the blade-side cavity. This seal is made by only partially permeable to the oil seals. As a result, it is possible to prevent the oil reservoir located in this chamber from being emptied during the operation of the rotor and displacing the entire oil located in the inner chamber of the rotor hub into the outer chamber.

Due to the overflow pipes, when the rotor is at a standstill, the oil can be discharged from the outer chamber into the inner chamber and collect again (essentially completely) in the inner chamber of the rotor hub.

This ensures adequate lubrication and protects the device against overheating.

In the embodiment according to claim 2, the adjustment of the orientation of the blades takes place by means of a hydraulic adjusting motor. The drive torque of the hydraulic variable displacement motor keeps the blades in the correct delivery position during operation of the axial fan.

The design with the hydraulic adjusting motor has the advantage that a hydraulic motor has good performance data with a comparatively low weight.

In the embodiment according to claim 3, the restoring torque of the blades is at least partially compensated by counterweights.

Advantageously, this relieves the adjustment motor so that it does not have to apply the required forces for adjusting the orientation of the rotor blades during operation of the axial fan alone.

Fig. 1:

einen Axial-Ventilator mit Laufschaufeln,

Fig. 2:

einen Axial-Ventilator in einer Draufsicht auf eine Schnittdarstellung bei Stillstand des Rotors,

Fig. 3:

die Lagerung der Laufschaufeln in der Laufradnabe,

Fig. 4:

ein Ausführungsbeispiel für die Einstellung der Orientierung der Laufschaufeln und

Fig. 5:

einen Axial-Ventilator, bei dem im Unterschied zur Darstellung der Figur 1 das Kegelrad direkt von der Verstellantriebswelle angetrieben wird.

An embodiment of the invention is shown in the drawing. It shows:

Fig. 1:

an axial fan with blades,

Fig. 2:

an axial fan in a plan view of a sectional view at standstill of the rotor,

3:

the bearing of the blades in the impeller hub,

4:

an embodiment for adjusting the orientation of the blades and

Fig. 5:

an axial fan, in contrast to the representation of the FIG. 1 the bevel gear is driven directly by the adjusting drive shaft.

FIG. 1 shows an axial fan with blades 11, wherein the blades 11 have a flow profile. The orientation of the blades 11 on the impeller hub 10 is adjustable by rotating the blades 11 about their longitudinal axis. The blades 11 are mounted on rails 12 on the impeller hub 10. On the spars 12 of the blades 11, a bevel pinion 13 is arranged in each case, wherein the bevel pinion 13 engage in a bevel gear 14 with a planetary gear on the Verstellantriebswelle 15.

As a result, the blades are rotatable about their longitudinal axis and can be adjusted either before starting the axial fan or during operation in terms of their angle of attack. In particular, the blades can also be rotated by 180 degrees, so that the conveying direction of the axial fan is reversible. It follows that the efficiency and the performance data for both directions are practically the same.

Furthermore, the shows FIG. 1 an embodiment for the lubrication of the rotating bearings of the adjustable blades and the gears of the adjusting gear. The impeller hub 10, which drives the axial fan, contains a constant oil charge. This oil is initially distributed when starting the fan in an inner chamber 16 of the impeller hub 10 and flows through the adjusting gear. In this case, a part of the oil is retained by a retaining ring 21. The part of the oil not retained by the retaining ring 21 flows through the inner hollow bearing 22. In this inner hollow bearing 22, part of the oil is retained before it reaches the outer radial hollow bearing 23 and is distributed annularly in the outer chamber 17 of the impeller hub 10. The inner chamber 16 and the outer chamber 17 of the impeller hub 10 are separated by the wall 18 from each other.

In this wall 18 are overflow tubes 24. When the rotor is stopped, the oil collects in the lower region of the impeller hub 10 and is from the outer chamber 17 through the overflow tubes 24 in the - at standstill of the rotor - lower portion of the impeller hub 10 in the inner Chamber 16 pressed. When restarting the rotor, the oil is then redistributed as described above.

There are still balancing weights 25 to see. These balance weights counteract a restoring moment of the blades 11. As a result, the adjustment drive motor as well as the adjusting gear is relieved, which would otherwise have to apply the forces for compensating the restoring moments of the blades 11 during operation of the rotor.

FIG. 2 shows an axial fan in a plan view of a sectional view at standstill of the rotor. In this case, the oil has collected in the lower region of the rotor 10. The oil filling 201 is distributed in the two chambers 16 and 17. Through this oil filling 201 during transmission and beyond the gear and bearing lubrication is maintained during operation. When the axial fan is switched off, an excess amount of the oil in the inner chamber 16 is automatically returned and accumulates in the lower half of the impeller hub (10).

The presentation of the FIG. 2 shows an embodiment with a planetary gear. It can be seen that the lubrication described in connection with Fogur 2 can also be used if the bevel gear is driven directly by the adjusting drive shaft. This embodiment is not shown in detail.

According to the presentation of the FIG. 3 the blades are pivotable in the impeller hub and stored without play.

The pivoting range 19 of the moving blades may be so great that the bevel gears 14 can be used to pivot the bevel gears 13 through 180 ° and more.

In the presentation of the FIG. 3 is designated by the arrow 301, the direction of rotation and the arrow 302, the flow direction.

According to the presentation of the FIG. 4 the adjustment of the orientation of the blades can be done so that when switching from forward to reverse operation and reverse direction of the electric drive motor first, the blade 11 with the airfoil by the angle ß (19) with 180 ° and more can be pivoted to the operating point for reversing (20) is reached.

It has been found that in the reversing operation, the delivery rate of the axial fan is more than 80% of the delivery rate power in forward mode and thus almost equal to a measured characteristic of an axial fan in forward mode. The capacity can be performed by the adjustable blades as in an axial fan with blade adjustment.

In the presentation of the FIG. 4 is indicated by the arrow 401, the direction of rotation and the arrow 402, the flow direction.

FIG. 5 shows an axial fan, which is largely the embodiment of the FIG. 1 equivalent. Identical components are provided with the same reference numerals. In contrast to the representation of the FIG. 1 is in the embodiment of FIG. 5 the bevel gear 14 directly driven by the Verstellantriebswelle 15 without a planetary gear is interposed (as shown in the illustration of FIG. 1 the case is).

As related to FIG. 2 explained, the local conditions in the lubrication are also applicable to a design in which according to the representation of FIG. 5 the bevel gear 14 is directly driven by the Verstellantriebswelle 15 (without a planetary gear).

Claims (3)

1. Axial fan with rotor blades (11), wherein the rotor blades (11) comprise a flow profile, wherein the orientation of the rotor blades (11) on the rotor hub (10) is adjustable in that the rotor blades (11) are rotatable around their longitudinal axis, wherein the rotor blades (11) are mounted on the rotor hub (10) via struts (12), wherein a bevel pinion (13) is respectively arranged on the struts (12) of the rotor blades (11), wherein the bevel pinions (13) engage with a bevel gear (14), which can be driven via an adjustable drive shaft (15),
   characterized in that the rotor hub (10) comprises an inner chamber (16), wherein an oil filling (201) is present in the inner chamber (16), wherein the rotor hub (10) further comprises an outer chamber (17), wherein the inner chamber (16) and the outer chamber (17) are connected via multiple openings, which respectively comprise a sealing system, which permits through a portion of the oil and holds back a portion of the oil, wherein, through these sealing systems, the bearings (22, 23) of the struts (12) of the rotor blades (11) are lubricated at least during the operation of the axial fan, wherein the outer chamber (17), at the radially inner end region, is in connection with the inner chamber (16) of the rotor hub (10) via overflow pipes (24), through which, when shutting down the axial fan, the oil at least partially flows back into the inner chamber (16) of the rotor hub (10).
2. Axial fan according to claim 1,
   characterized in that the adjustment of the orientation of the rotor blades (11) occurs by means of a hydraulic adjustable motor, wherein the drive torque of the hydraulic adjustable motor keeps the rotor blades (11) in the correct conveying position during the operation of the axial fan.
3. Axial fan according to claim 2,
   characterized in that the restoring torque of the rotor blades (11) is at least partially compensated for via counterweights (25).

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