EP0863314B1 - Side-channel compressor with tapered channel - Google Patents

Description

The invention relates to a side channel compressor according to the preamble of the claim 1.

Side channel blowers are used in many industries to compress Air and technical gases, as compressors in the rough vacuum range, for example in the paper industry, the printing industry, etc., and as compressors used to generate excess pressure.

Like all turbo compressors, side channel compressors must also be considered high efficiencies can be designed for the nominal point. Here, the permissible Operating area considering the justifiable minimum polytropic Coupling efficiency set to be an optimal polytropic overall To achieve efficiency.

So far, the design of the compressors, in particular the side channel, has been carried out for incompressible flow, i.e. neglecting the change in density, with constant cross-section of the side channel in the entire circumferential area. The consequence of which is that in the pressure area of the side channel there are no optimal speed ratios can be achieved that correspond to the density ratio. hereby both the transfer of work and the efficiency are impaired.

From DE 42 20 153 A1 an eddy current fan with a housing is known, the has an annular flow passage extending from an inlet opening extends to receive fluid up to a fluid outlet opening. in this connection becomes for noise reduction in a predetermined delimited section a flow reducer is arranged in the flow passage. This achieved thereby a noise reduction that in the corresponding area between Inlet opening and outlet opening through a constantly reduced cross section of the flow passage resulting from the breaking off of the flow Turbulence can be avoided and consequently the occurrence of noise and a loss of pressure is prevented. However, after the predetermined section, in which the cross-section reducer is arranged, again a cross-sectional expansion, thus no restricted air volume with accordingly reduced delivery rate is present. This also has the above Disadvantages that the side channel neglecting the change in density of the fluid conveyed in the side channel is formed. Therefore, this system also shows no optimal speed conditions in the pressure area of the side channel, that would correspond to a prevailing density ratio. Therefore be here, too, both the transfer of work and the efficiency are impaired.

DE-PS 876 285 describes a ring compressor or rotary compressor Side channel. Here, the cross section of the work area should correspond to the increasing Compaction and the decreasing specific volume of the conveyed material Decrease steadily along the circumference in the direction of rotation.

US 4,325,672 describes a side channel compressor for compressing, pumping or blowing air or other gases. Corresponding rotor blades are designed such that a fluid flow with respect to the rotor blades An angle greater than 90 degrees results.

Document GB 606 127 describes a centrifuge blower with an annular channel, the cross section of which decreases from the inlet to the outlet. In the ring channel is an impeller with wing blades arranged such that when the impeller rotates the air inside the ring channel not only in the axial direction along the Ring channel but also rotates about an axis of the ring channel, so that the air repeatedly comes into the area of influence of the wing blades. The cross-sectional reduction is designed so that it follows the compression of the material to be conveyed.

The invention is based, to eliminate the side channel blower the task to design the disadvantages described so that improved Efficiency an increase in volume flow with a uniform Pressure increase in the side channel results.

The features of the invention created to achieve this object result itself from claim 1. Advantageous refinements of this are in the others Described claims.

The side channel compressor designed according to the invention has a modified one Cross section of the side channel, in such a way that the cross section of the side channel tapers from the suction side towards the pressure side. The cross-sectional taper of the side channel based on the cross-section on Gas inlet has a value in the range of 20% to 40%, so that the Cross section of the side channel from 130% at the gas inlet to 100% at the gas outlet rejuvenated. This surprisingly achieves an optimal improvement in efficiency.

Through the modification of the side channel cross section provided according to the invention a change in the funding characteristics can generally be achieved. This means that larger volume flows can be achieved with a larger duct cross-section. However, the amount of pressure increase is reduced here. About this characteristic To counteract, is a tapered side channel cross section according to the invention intended.

It is particularly advantageous if the cross section of the side channel is continuous or continuously rejuvenated.

Overall, this advantageous embodiment results from this embodiment according to the invention achieved that the enlarged channel cross-section in the suction area improved Expansion of the gas ensures that the pressure side through the interrupter entry. This means that a vacuum can also be achieved at a lower level and the suction power increases.

In addition, due to the tapering cross-sectional area, in particular continuously of the side channel in the housing achieved an additional compression of the gas. As a result, there is a high and constant polytropic exponent throughout Side channel.

In an advantageous modified embodiment is in the side channel Housing cover an inward-pointing flow guide edge for the pumped Media arranged. This flow guide edge is in the form of a tapered Rib formed, advantageously the cross section of the flow leading edge adapted to the tapering cross section of the side channel is.

The flow guide edge can be formed in one piece with the wall of the side channel his. Instead, the flow leading edge can also be on a separate Guide ring formed in the side channel at the corresponding desired Place used on the inner wall or attached there.

The advantageous effect of this flow guide edge is that there is a considerable efficiency improvement of the side channel compressor results. This can be 5 'to 9%. The improvement in efficiency is achieved through the improved flow design in the side channel achieved, which in turn is caused by the flow leading edge. When operating the side channel blower the open impeller pushes the media to be conveyed out of the impeller and pushes it against the outer cylinder wall of the in the housing or side channel in the lid. There takes place on the perpendicular to the flow standing cylinder wall surface of the side channel the deflection of the flow in the outer side channel area. This is when the flow guide edge described is provided, an improved deflection of the flow is achieved.

Fig. 1

den Deckel eines Seitenkanalverdichters in Draufsicht sowie

Fig. 2

im Querschnitt gemäß Linie II - II von Fig. 1,

Fig. 3, 4, 5 und 6

verschiedene Querschnittsformen des Seitenkanals gemäß den Linien A - A, B - B, C - C und D - D von Fig. 1;

Fig. 7

im Schnitt eine abgewandelte Ausführungsform des Seitenkanals mit einer einstückig ausgeformten Strömungsleitkante;

Fig. 8

eine abgewandelte Ausführungsform mit einem die Strömungsleitkante aufweisenden gesonderten Leitring in Draufsicht und

Fig. 9

im Querschnitt gemäß Linie IX - IX von Fig. 8;

Fig. 10

schematisch im Schnitt einen Seitenkanalverdichter mit einem einkränzigen Laufrad in radialer Bauart mit einem halbkreisförmigen Seitenkanalquerschnitt;

Fig. 11

schematisch einen sog. doppelflutigen Seitenkanalverdichter im Schnitt und

Fig. 12

im horizontalen Querschnitt hierzu sowie

Fig. 13

die Abwicklung eines Seitenkanals mit dem sich von der Saugseite zur Druckseite hin verjüngenden Seitenkanalquerschnitt.

The invention is explained below with reference to the drawing. This shows in:

Fig. 1

the cover of a side channel blower in top view and

Fig. 2

in cross section along line II - II of Fig. 1,

3, 4, 5 and 6

different cross-sectional shapes of the side channel according to the lines A - A, B - B, C - C and D - D of Fig. 1;

Fig. 7

in section a modified embodiment of the side channel with an integrally formed flow guide edge;

Fig. 8

a modified embodiment with a separate guide ring having the flow guide edge in plan view and

Fig. 9

in cross section according to line IX - IX of Fig. 8;

Fig. 10

schematically in section a side channel blower with a single ring impeller in radial design with a semicircular side channel cross section;

Fig. 11

schematically a so-called. Double-flow side channel blower in section and

Fig. 12

in horizontal cross-section for this as well

Fig. 13

the processing of a side channel with the side channel cross-section tapering from the suction side to the pressure side.

As can be seen from FIGS. 1 and 2 of the drawing, a side channel compressor has impeller equipped with blades, which is used to compress gases in one Housing is rotatable.

The housing is provided with a cover 1, which has a gas inlet 2 and a Has gas outlet 3 and, as can be clearly seen from Fig. 2, on the impeller facing side a side channel 4 limited.

The cross section of the side channel 4 is bowl-shaped and designed such that he from the gas inlet 2 (suction side) towards the gas outlet 3 (pressure side) rejuvenated. Here, the tapering of the side channel cross section takes place in the illustrated Embodiment continuously or continuously.

In detail, the cross-sectional taper is in the embodiment shown such that the cross section of the side channel 4 at the point D - D according to 1 in the manner shown in FIG. 6 is 130%. Tapered from here then the cross section of the side channel 4 steadily over 122% of the Interface C - C according to FIG. 1 (see FIG. 5) and over 107% at the interface B - B according to FIG. 1 (see FIG. 4) except for 100% at the interface A - A or near the gas outlet 3 (see Fig. 3).

7 is in the inner wall of the Side channel 4 formed a flow guide edge 5, which tapers conically is formed and points inward in the manner shown. This flow leading edge 5 is formed in one piece with the wall of the side channel 4 and serves for the corresponding redirection of the flow of the media to be conveyed the outer area of the side channel 4. This will result in a better deflection the flow, which results in an efficiency improvement of 5 to 9%.

The formation of the flow leading edge 5 over the entire circumference of the side channel 4 is selected such that the cross section of the flow guide edge 5 on the tapering cross section of the side channel 4 is adapted.

7, as explained, the flow guide edge 5 is integrally formed with the wall of the side channel 4, is in the modified embodiment according to FIGS. 8 and 9 on the flow guide edge 5 a separate guide ring 6 is provided, which in the manner shown in FIG. 8 is formed and inserted into the interior of the side channel 4 or there is attached that the flow guide edge 5 in the same manner as in the previously described Embodiment according to FIG. 7 shows inwards. This one too Embodiment becomes the same effect in efficiency improvement as achieved in the embodiment of FIG. 7.

The representations in FIGS. 10 and 11, 12 serve as a supplementary explanation the operation of a side channel blower and show schematically in Fig. 10 a side channel blower with a single ring impeller 7 in radial Type with a semicircular cross section of the side channel 4, wherein the side channel is formed in the housing or cover 1. The in Fig. 10 The arrows shown represent the flow of the media to be pumped, in such a way that the open impeller 7 with its blades to be promoted Medium pushes out of the impeller 7 and this against the wall of the in the cover 1 side channel 4 presses. From there the flow becomes like this deflected that the medium to be conveyed is pressed into the impeller 7 again.

In the modified embodiment of the side channel compressor according to FIG. 11 and 12 a so-called double-flow side channel compressor is provided. Here is 11, the impeller 7 is formed with a double blade ring, one blade assembly from the other blade assembly is averted. Each blade ring unit is a side channel 4, which on one Lid is arranged, assigned.

In each of the two schematically explained embodiments according to FIG. 10 and 11 is the cross-sectional tapering of the side channel provided in accordance with the invention present, as can be clearly seen from Fig. 12. Here, the tapered Cross section of the side channel 4 from the gas inlet 2 (suction side) towards Gas outlet 3 (pressure side).

This design is also clear from the illustration according to FIG. 13, which shows a development of the side channel 4 on the suction or pressure side can be seen. Here is the cross section of the side channel 4 at the gas inlet 2, the is separated from the gas outlet 3 by an interrupter web 8, opposite the Cross section near the gas outlet expanded by the amount that by the hatched area 9 is marked.

Claims (6)

1. Side channel compressor with an impeller provided with blades which is rotatable in a housing equipped with a side channel (4) for compressing gases, whereby on a suction side an inlet opening (2) is formed and on a compression side an outlet opening (3) is formed in fluid-conducting connection with the side channel (4) and the cross-section of the side channel (4) tapers, starting from the suction side (2), from the inlet opening (2) in the direction towards the compression side (3) as far as the outlet opening (3), characterised in that the cross-sectional narrowing of the side channel (4) has a value related to the cross-section at the gas inlet (2) in the range of 20% to 40%, so that the cross-section of the side channel (4) tapers from 130% at the gas inlet (2) to 100% at the gas outlet (3).
2. Side channel compressor according to Claim 1, characterised in that the cross-section of the side channel (4) tapers continuously.
3. Side channel compressor according to one of the previous claims, characterised in that arranged in the side channel (4) of the housing cover (1) is a flow guide edge (5) directed inwards for the media to be supplied.
4. Side channel compressor according to Claim 3, characterised in that the cross-section of the flow guide edge (5) is adapted to the tapering cross-section of the side channel (4).
5. Side channel compressor according to Claim 3 or 4, characterised in that the flow guide edge (5) is formed in one piece with the wall of the side channel (4).
6. Side channel compressor according to Claim 3 or 4, characterised in that the flow guide edge (5) is formed on a guide ring (6) inserted into the side channel (4) with the flow guide edge (5) directed inwards, or is attached there.

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