EP4063663A1 - Bladeless flow diffuser - Google Patents

Abstract

The invention relates to an axial fan (1) with a housing (2) forming a flow channel (3) and a fan wheel (5) accommodated in the housing (2) and rotatable about an axis of rotation (RA), the fan wheel (5) having a hub (25) from which fan wheel blades (16) extend radially outwards, and wherein the fan wheel (5) forms a hub diffuser (26) on the outflow side on the hub (25), which axially adjoins a region of the hub (25). , In which the fan wheel blades (15) of the fan wheel (5) are formed, so that the hub diffuser (26) is free of fan wheel blades (15).

Description

The invention relates to an axial fan with a housing that forms a flow channel and a fan wheel that is accommodated in the housing and can be rotated about an axis of rotation.

A large number of axial fans in a single-stage or multi-stage design, i.e. with one or more fan wheels that generate the axial flow, are known from the prior art.

The invention is aimed at improving aerodynamic efficiency and thereby also reducing the power consumption in such axial fans. In addition, the flow-related noise should be reduced.

This object is achieved by the combination of features according to claim 1.

According to the invention, an axial fan is proposed with a housing forming a flow channel and a fan wheel accommodated in the housing and rotatable about an axis of rotation, in which the fan wheel has a hub from which fan wheel blades extend radially outwards. On the outflow side, the fan wheel forms a hub diffuser on the hub, which axially adjoins an area of the hub in which the fan wheel blades of the fan wheel are formed, so that the hub diffuser is bladeless, i.e. free of fan wheel blades. The hub diffuser can be used to delay the flow velocity at the downstream end and behind the impeller. This is done by gradually reducing the hub diameter and the associated increase in the free flow cross section in the flow channel. It is crucial that the hub diffuser is unaffected by the impeller blades. This is achieved in that the impeller blades end axially in front of the hub diffuser, so that a hub diffuser wall surface facing the flow channel is formed without impeller blades and only the tapering cross-section of the hub diffuser wall surface acts on the downstream flow.

According to the invention, the dynamic exit losses, the power consumption and the generation of noise are reduced.

Also advantageous is an embodiment variant of the axial fan in which an axial section in the flow channel of the axial fan, in which the hub diffuser is formed, is formed as a free space through which air can flow freely. This means that the hub diffuser wall surface is not only free of impeller blades, but that the hub diffuser wall surface is formed free of any components such as webs or other flow guide elements as well as the free space in the flow channel adjoining the hub diffuser wall surface radially. The flow can thus flow freely and unaffected through the flow channel in the axial section of the hub diffuser.

An advantageous development of the axial fan is also characterized in that the housing has an outlet on the outflow side and a housing diffuser at the outlet, with the fan wheel being positioned within the housing in such a way that the hub diffuser of the fan wheel and the housing diffuser of the housing overlap in an axial plane. The hub diffuser and the housing diffuser together have a positive effect on the flow at the outlet of the axial fan. It is also favorable if the housing diffuser has a rounded housing diffuser wall surface and the hub diffuser has a conical hub diffuser wall surface.

In terms of value, it is advantageous in the case of the axial fan if the hub diffuser and the housing diffuser increase a flow channel cross-sectional area of the flow channel at the outlet by a total of 25-30%.

A design in which the entire axial extent of the hub diffuser is greater than the entire axial extent of the housing diffuser also has a favorable effect in terms of flow technology in the case of the axial fan for solving the tasks.

Geometrically, an embodiment is also advantageous for the axial fan in which a radial indentation of the hub diffuser relative to the hub is less than a radial indentation of the housing diffuser relative to a housing inner wall surface axially adjoining the housing diffuser. In the present case, radial indentation is understood to mean the reduction in the extension in the radial direction perpendicular to the axis of rotation.

The invention is particularly advantageous in the case of multi-stage axial fans. In one embodiment of the invention, the fan wheel is therefore arranged axially in series with at least one second fan wheel. During operation, the fan wheels together generate an axial flow through the flow channel, the fan wheel with the hub diffuser being positioned on the outflow side and the second fan wheel being positioned on the intake side.

Also advantageous is an embodiment of the axial fan in which a non-rotatable web arrangement with a plurality of radial webs is provided axially between the fan wheel and the second fan wheel, which extend radially through the flow channel and have a curved profile, which is designed to have an im Operation to convert generated swirl of the axial flow of the first fan wheel in static pressure. The curved profiling can take place through a three-dimensional curvature of the radial webs, so that the radial webs form flow guide surfaces along the axial flow direction, which influence the axial flow aerodynamically.

In a further development of the multi-stage axial fan, it is provided that it comprises an annular part which forms part of the housing and comprises the web arrangement with the radial webs. The ring part thus makes a contribution to the structural design and to the aerodynamics of the axial fan.

The ring part is preferably designed in one piece. In one embodiment, it has a ring element and an axially central motor mount which is coaxial with the ring element and to which at least one motor of the axial fan can be fastened. The ring element forms part of the housing, the motor mount is another constructive part for integrating the motor or motors of the impellers. In the case of the ring part, the radial webs preferably extend from the ring element to the motor mount through the flow channel. Furthermore, for a compact axial structure, the fan wheel and the second fan wheel are preferably each arranged directly adjacent to the annular part.

A development of the axial fan is also characterized in that the fan wheel has impeller blades with a first axial extent and the second fan wheel with impeller blades with a second axial extent, the first axial extent being greater than the second axial extent. This constructive solution also contributes to the solution of the tasks. By using the radial webs with a curved profile, on which the static pressure is built up, the load and the speed of the following impeller blades of the second fan wheel are reduced and the axial extension can be reduced. This in turn has a positive effect on providing the hub diffuser in the fan wheel, since the axially shorter impeller blades on the fan wheel create axial space for the hub diffuser.

Fig. 1

eine erste seitliche Schnittansicht durch einen Axiallüfter;

Fig. 2

eine zweite seitliche Schnittansicht durch den Axiallüfter aus Figur 1;

Fig. 3

eine Detailansicht X aus Figur 2;

Fig. 4

eine Schnittansicht F-F aus Figur 2;

Fig. 5

eine Schnittansicht G-G aus Figur 2;

Fig. 6

eine perspektivische Ansicht eines Ringteils des Axiallüfters aus Figur 1.

Other advantageous developments of the invention are characterized in the dependent claims or are presented in more detail below together with the description of the preferred embodiment of the invention with reference to the figures. Show it:

1

a first side sectional view through an axial fan;

2

a second side sectional view through the axial fan figure 1 ;

3

a detail view X figure 2 ;

4

a sectional view FF figure 2 ;

figure 5

a sectional view of GG figure 2 ;

6

a perspective view of a ring part of the axial fan figure 1 .

In the figures 1 and 2 an exemplary embodiment of an axial fan 1 in a multi-stage design is shown in lateral sectional views.

The axial fan 1 comprises a three-part, nested housing 2, in which the first fan wheel 4, the fixed, non-rotatable web arrangement 6 and the second fan wheel 5 are accommodated, viewed axially in a row in the direction of flow S, and together the flow channel 3 parallel to the axis of rotation RA of the fan wheels 4, 5 determine. The two fan wheels 4, 5 generate the axial flow AS through the flow channel 3, with the proportion of the axial flow AS generated by the first fan wheel 4 initially flowing against the web arrangement 6 and then being carried on by the second fan wheel 5. The non-rotatable web arrangement 6 is formed by the ring part 10 and comprises a plurality of radial webs 7. In addition, a wall insert 93 (see figure 2 ) to compensate for the rectangular or square outer contour provided in a flow channel 3 with a round cross section.

The ring part 10 is in figure 6 shown closer. It is designed in one piece with the ring element 11, which forms part of the housing 2, an axle-central motor mount 12 with an outer ring 12 and two hollow-cylindrical axial sockets 80, 81 for fastening the motors 44, 45 on the outside and the motor bearing on the inside (see Fig figure 1 ). Between the axial sockets 80, 81 and the outer ring 12, a plurality of recesses 22 through which flow can flow and stiffening struts 23 are alternately distributed in the circumferential direction. Thus, cooling air can also get into the area of the motors 44, 45 and flow through the recesses 22. The radial webs 7 of the web arrangement 6 extend radially between the ring element 11 and the outer ring 76 of the motor mount 12. The axial extent of the radial webs 7 in their radially outer edge section, in which they are connected to the ring element 11, is greater in terms of amount than the axial extent in the radially inner edge section, which is respectively attached to the outer ring 76 of the engine mount 12 is connected. The outer ring 76 is coaxial with the ring element 11.

Each of the radial webs 7 has the same shape and each has the leading edge 8 and the trailing edge 9 . Viewed from a radial plane, the leading edge 8 is more curved than the trailing edge 9. The radial webs 7 extend radially through the flow channel 3 and have a curved profile. In the embodiment shown, the radial webs 7 are curved both in the circumferential direction and in the axial direction. A three-dimensional curvature of the radial webs 7 results in at least two directions. This results in flow guide surfaces 77 on the radial webs 7 along the axial flow direction S, so that these are designed to convert a swirl of the axial flow of the first fan wheel 4 generated during operation into static pressure. The remaining twist is then removed by the second fan wheel 5 with a low build-up of static pressure. In the embodiment shown, the two fan wheels 4, 5 rotate in opposite directions during operation.

Referring again to the figure 1 and 2 the first fan wheel 4 has the hub 24 from which the impeller blades 14 extend radially outwards. The second fan wheel 5 has the hub 25 from which the impeller blades 15 extend radially outwards. The hubs 24, 25 each run parallel to the motor mount 12 in the axial plane AE and thus form a radially inner wall surface of the flow channel 3 parallel to the axis of rotation RA. An interruption is provided between the hubs 24, 25 and the outer ring 76 of the motor mount 12, so that air can flow into the area of the axial sockets. In addition, it is provided that the first fan wheel 4 has impeller blades 14 with a greater axial extent than the second fan wheel 5 . Axially adjoining the impeller blades 15, the hub diffuser 26 is formed on the hub 25 of the second fan wheel 5 with a cross section that tapers conically. The axially shorter impeller blades 15 on the second fan wheel 5 are only arranged in the section of the hub 25 parallel to the axis of rotation, so that the hub diffuser wall surface of the hub diffuser facing the flow channel 3 is formed without impeller blades 15 or other components and only the tapering cross section of the hub diffuser wall surface on the downstream side flow acts. The area in the flow channel 3 adjoining the second impeller 5 in the direction of flow can be freely traversed, so that the axial section of the axial fan with the hub diffuser 26 is designed as a freely traversable free space.

In figure 2 the housing diffuser 27 formed at the outlet of the housing can be clearly seen, which has a rounded housing diffuser wall surface. The fan wheel 5 with its hub 25 is positioned within the housing 2 in such a way that the housing diffuser 27 and the hub diffuser 26 overlap in an axial plane. Both diffusers thus work together directly and increase the flow channel cross-sectional area of the flow channel 3 at the outlet in the embodiment shown by 28%, as can also be seen in the sectional views F and G of FIG Figures 4 and 5 can be seen. The following applies to the lengths T2>T1 and the curves R3>R1 and R2>R4.

In the detail view X off figure 2 , what a figure 3 is shown, it is also easy to see that the axial extent L2 of the hub diffuser 26 is greater than the axial extent L1 of the housing diffuser 27 and that the radial retraction H2 of the hub diffuser 26 compared to the hub 25 is less is as the radial indentation H1 of the housing diffuser 27 in relation to the housing inner wall surface which adjoins the housing diffuser 27 axially and extends parallel to the axis of rotation RA. Seen in the direction of flow, a short section of the hub 25 initially adjoins the second fan wheel 5 in an extension parallel to the axis of rotation, before the hub diffuser 26 is connected and determines the axial termination of the impeller 5 . The axial end of the impeller 5 is set back slightly in the interior of the flow channel 3 with respect to the axial plane, which determines the outlet of the housing 2 and thus the closure of the axial fan 1 .

The embodiment of the invention is not limited to the preferred exemplary embodiments specified above, in particular not to the embodiment of multi-stage axial fans. However, the advantageous fluidic effect is particularly pronounced in the multi-stage design.

Claims (12)

Axial fan (1) with a housing (2) forming a flow duct (3) and a fan wheel (5) accommodated in the housing (2) and rotatable about an axis of rotation (RA), the fan wheel (5) having a hub (25). , from which fan wheel blades (16) extend radially outwards, and wherein the fan wheel (5) forms a hub diffuser (26) on the outflow side on the hub (25), which axially adjoins an area of the hub (25) in which the Fan wheel blades (15) of the fan wheel (5) are formed so that the hub diffuser (26) is free of fan wheel blades (15). Axial fan according to Claim 1, characterized in that an axial section in the flow channel (3) of the axial fan, in which the hub diffuser is formed, is formed as a free space through which air can flow freely. Axial fan according to Claim 1 or 2, characterized in that the housing (2) has an outlet on the outflow side and a housing diffuser (27) at the outlet, the fan wheel (5) being positioned within the housing (2) in such a way that the hub diffuser (26 ) of the fan wheel and the housing diffuser (27) of the housing overlap in an axial plane. Axial fan according to the preceding claim, characterized in that the hub diffuser (26) and the housing diffuser (27) increase a flow channel cross-sectional area of the flow channel (3) at the outlet by 25-30%. Axial fan according to one of the preceding claims 3 to 4, characterized in that an axial extent (L2) of the hub diffuser (26) is greater than an axial extent (L1) of the housing diffuser (27). Axial fan according to one of the preceding claims 3 to 5, characterized in that a radial indentation (H2) of the hub diffuser (26) in relation to the hub (25) is less than a radial indentation (H1) of the housing diffuser (27) in relation to a Housing diffuser (27) axially adjoining housing inner wall surface. Axial fan according to one of the preceding claims, characterized in that the fan wheel (4) is arranged axially in series with a second fan wheel (5) and the fan wheels (4, 5) generate an axial flow (AS) through the flow channel (3) during operation . Axial fan according to the preceding claim, characterized in that a non-rotatable web arrangement (6) with a plurality of radial webs (7) is provided axially between the fan wheel (4) and the second fan wheel (5) and extends radially through the flow channel ( 3) extend and have a curved profile which is designed to convert a swirl of the axial flow of the first fan wheel (4) generated during operation into static pressure. Axial fan according to one of the preceding claims 7 or 8, characterized in that the axial fan (1) comprises an annular part (10) which forms part of the housing (2) and comprises the web arrangement (6). Axial fan according to the preceding claim, characterized in that the ring part (10) has a ring element (11) and an axially central motor mount (12) which is coaxial with the ring element (11) and on which at least one motor (44, 45) of the axial fan ( 1) can be attached. Axial fan according to the previous claim, characterized in that the radial webs (7) extend from the ring element (11) to the motor mount (12) extend. Axial fan according to one of the preceding claims 7 to 11, characterized in that the fan wheel (4) has impeller blades (14) with a first axial extent and the second fan wheel (5) has impeller blades (15) with a second axial extent, the first axial extent being greater is than the second axial extent.

Images