DE19703292A1 - Fan impeller for e.g. non-positive displacement pump - Google Patents

Abstract

The impeller has a width ratio, b2/D of between (0.2,0.6) and a predominant radial throughflow. The radial extent, (D-d1) /D of the radial impeller blade grid (1) reduces from a region of the support wheel (2) to the cover wheel (3). The exit edges (4) of the blades rise outwardly, whereby the grid outlet diameter D increases. The support wheel is inclined against the direction of flow and towards the rotational axis of the impeller. The radial blade lattice begins at the support wheel when the radial ratio, d1/D is greater than or equal to (0.5), and stops when it is greater than or equal to 75.

Description

The invention relates to an essentially radially flowed impeller with a large width ratio b ₂ / D in the range from 0.3 to 0.6 for radial fans.

Fan impellers with width ratios b ₂ / D <03 and relatively large diameter ratios d ₁ / D = 0.8 to 0.85 are known. Their leading and trailing edges run essentially parallel to the axis of rotation of the fan. Because of their external shape, they are also called drum rotors. They usually have very forward curved blades with blade entry angles of β ₁ ≈ 90 ° and exit angles at β ₂ ≈ 170 ° and thus work in terms of maximum efficiency with a large volume number ϕ from 0.4 to 0.8 and a large pressure number ψ of 2. 5 to 3. These forward curved blades are relatively stable against centrifugal forces, despite the large impeller width. Due to the large pressure number and performance figures λ = ϕ. ψ in the range from 0.25 to 4.0, they can run at relatively low speeds with small installation dimensions.

The big disadvantage of these radial wheels is that in Paddle grate the majority of the fed to the impeller Drive energy not in static pressure energy, but in dyna mixed energy is implemented. This can only be partial and strong lossy in the spiral housing required below and converted into static pressure.

Another disadvantage is that the absolute outflow velocity c _{3 is} due to the combination of the high pressure number with the large delivery number

ϕ _r = c _{2, r / u 2} = ϕ D / (4 b ₂ )

according to the Euler equation for swirl-free inflow

cotg α ₃ = ψ _th / (2 ϕ _r )

with a relatively small exit angle α3 out of the impeller occurs.

In addition, because of the relatively large width of the Impellers the leading edges of the blades especially in the The area of the support disk has an uneven flow. Thereby and due to the predominantly cylindrical / prismatic design of the Blades are relative efficiencies of such fans low and hardly exceed 70%.

The losses due to the low efficiency, the uneveni flow and the high and varied speed in and behind the wheel are also one of the reasons why that the specific sound power level is approx. 10 dB (A) higher than at usual high-performance centrifugal fans.

Therefore, for wide fans with a diameter ver ratio by 0.7 and a width ratio b2 / D greater than 0.2 rotating multi-radial diffusers proposed (DE 39 19 111 A1). These could have the disadvantages mentioned above, such as the high ones Leakage losses with forward curved blades with large Pressure number or the low strength in backward curved Only reduce buckets. The disadvantages of an unfavorable situation Impact of the vane grille combined with the unfavorable Velocity profiles in the outflow area of the blade grids but could not be eliminated.

The aim of the invention is to avoid the disadvantages mentioned and an improvement in energy economy, acoustic Behavioral and firmness.

The invention has for its object a substantially radially flowed, wide impeller with a width ratio b ₂ / D in the range of 0.3 to 0.6 for radial fans with a large number of pressures ψ and large numbers of volumes ϕ and thus a large coefficient of performance λ = ψ. To create und and thereby to improve the efficiency η _, to reduce the specific sound power level L _{W, spec} and to increase the strength of the wheel.

According to the invention, this object is achieved by the features of the claims by the radial extent (Dd ₁ ) / D of the blade grille with an impeller of wesent union radial design with a width ratio b ₂ / D in the range from 0.3 to 0.6 decreases from the area of the support disc to the cover disc.

In the embodiment of the blade area according to the invention can use a vane grille in the area of the supporting disc find in which the strong in a grid of a work machine Load of the boundary layer through a longer blade channel in Limits are kept and premature detachment is prevented. This is the disadvantage of common drum rotors flow of the blade cuts or blade profiles in the area of Carrier disc due to lower speeds than in the deck disc avoided area. Next is the inventive Execution of the blades increases the rigidity of the wheel and its strength behavior improved.

The embodiment of the invention associated with the increase in Blade leading edge from the cover plate to the support plate also affects the uneven speed distribution towards the blade-free space behind the impeller. So that will the initial condition for a subsequent diffuser verbes sert, which is known to be good only with a decent inflow profile can work.

The effect of the execution of the impeller according to the invention can be increased by the radial inflow to the grid in the Area of the support disc due to the inclination of the support disc against the flow direction of the wheel to the axis of rotation is made more moderate. As an additional effect, there is a higher one  Strength by improving the stiffness of the support disk a.

In order to effectively reduce the high speeds behind the impeller, a combination of the design according to the invention with a known co-rotating diffuser has proven itself, which was created by extending the cover and / or support disk from D to d ₃ . In these diffusers, a strong increase in pressure is possible due to the radial throwing off of the boundary layer due to the centrifugal force. This effect is so great that, despite the unavoidable wobble dents behind the blades, an additional pressure increase is possible due to a further delay in the exit speed due to the expansion of the impeller width b from b ₂ to b ₃ in the radial direction. The transition from cover and support plate to the diffuser plates should preferably be rounded.

Finally, the combination of the invention Execution with suitable vane grids further improvements conditions can be achieved. Every second or nth bucket can be used for this purpose be shortened in the area of the support disk. So z. B. Speed increases in the area of the grille entry to be avoided with small diameter ratios due to the finite blade thickness. Furthermore can be offset by the offset of the shorter blades the speed distributions towards the longer blades the blades and their dents diminished favorably will. Acoustically favorable has a further effect if the Blades or their trailing edges obliquely to the direction of Axis of rotation or to the direction of flow are inclined.

Based on drawings in the following execution and Application examples of the invention are described in more detail.

Fig. 1 shows the meridian section of a running wheel according to the invention, in which the radial extent (Dd ₁ ) / D of the radial vane grille 1 from the area of the support plate 2 to the cover plate 3 decreases.

In FIG. 2, the radial extension of the radial blade cascade according to the invention takes from the carrying disc to the cover plate off at the same time, the outer diameter D off the blade cascade and the inlet diameter d ₁ increases.

In Fig. 3, the support plate 5 is inclined against the direction of flow towards the axis of rotation of the impeller.

Fig. 4 shows an advantageous embodiment of the invention, which d on the cover disc at a radius ratio ₁ / D ≈ 0.5 starts and ends on the cover plate at ≈ 0.75.

FIG. 5 shows an impeller designed according to the invention, the support disk 2 and cover disk 3 of which are enlarged by enlarging the blade outlet diameter D to d ₃ as limits of a rotating radial diffuser.

In Fig. 6, the diffuser part 6 of the support plate 2 and the diffuser part 7 of the cover plate 3 are arranged so that an expansion of the grid width b from b ₂ to b ₃ takes place in the flow direction.

In Fig. 7, an additional diffuser disc 8 supplements the radial diffuser to form a radial multi-diffuser.

Fig. 8 shows the meridian section of a radial wheel designed according to the invention, in which the blade trailing edges for receiving the additional diffuser disc 8 are offset (a) and the transitions from the poison area to the diffuser are rounded.

Fig. 9 to 11 show advantageous lattice designs in conjunction with inventive designs.

In FIG. 12, the blades or their trailing edges are inclined to the direction of the axis of rotation A or to the inflow direction R.

Claims (13)

1. Fan wheel with a large width ratio b ₂ / D in the range from 0.2 to 0.6 and predominantly radial flow, characterized in that the radial extension (Dd ₁ ) / D of the radial vane grille ( 1 ) from the area of the support disk ( 2 ) decreases up to the cover plate ( 3 ). 2. Fan wheel according to claim 1, characterized in that the trailing edges ( 4 ) of the blades from the cover plate ( 3 ) to the support plate ( 2 ) rise, the grid outlet diameter D increasing. 3. Fan wheel according to claim 1 and / or 2, characterized in that the supporting disc ( 5 ) against the Anströmrich device (R) to the axis of rotation (A) of the impeller is inclined. 4. Fan wheel according to one or more of claims 1 to 3, characterized in that the radial vane grille ( 1 ) on the support plate ( 2 ) begins at the radius ratio d ₁ / D greater than / equal to 0.5 and on the cover plate ( 3 ) greater than or equal to 0.75 ends. 5. Fan wheel according to one or more of claims 1 to 4, characterized in that its support plate ( 2 ) and cover plate ( 3 ) over the blade outlet diameter D from to d _{3 are} enlarged and form a rotating radial diffuser ( 6 , 7 ) . 6. Fan wheel according to one or more of claims 1 to 5, characterized in that the diffuser part ( 6 ) of the supporting disc ( 2 ) and / or the diffuser part ( 7 ) of the cover plate ( 3 ) are arranged so that an expansion of the impeller width b takes place from b ₂ to b ₃ in the direction of flow. 7. Fan wheel according to one or more of claims 1 to 6, characterized in that one or more additional diffuser disks ( 8 ) result in a radial multi-diffuser. 8. Fan wheel according to one or more of claims 1 to 7, characterized in that the blade trailing edges in the region of the additional diffuser disks ( 8 ) are offset (a). 9. fan wheel according to one or more of claims 1 to 8, characterized in that the radial extension of the co-rotating radial diffuser preferably 1.2 times the Grid outlet diameter D is. 10. Fan wheel according to one or more of claims 1 to 9, characterized in that the transitions from the Carrier or cover disc ran to the rotating radial diffuser det (g) are. 11. Fan wheel according to one or more of claims 1 to 10, characterized in that every second or nth blade ( 9 ) in the region ( 10 ) of the support disk ( 2 ) begins with a larger radius ratio d ₁ '/ D. 12. Fan wheel according to one or more of claims 1 to 11, characterized in that the shorter blades ( 9 ) are offset in the direction of the longer blades ( 11 ). 13. Fan wheel according to one or more of claims 1 to 12, characterized in that the blades or their trailing edges ( 4 ) to the direction of the axis of rotation (A) or the inflow direction (R) are inclined.