EP0372104A1 - Side channel compressor - Google Patents

Abstract

The invention relates to a side channel compressor with an impeller (4) rotatably mounted in its housing, which consists of a blade ring (7) arranged on a disk - shaped hub part (6) and a blade ring (7) arranged on the outer circumference of this hub part (6), in which compressor in the transition area from the blade ring (7) and hub part (6) a sealing gap (10, 11 and 21) is provided. In order to prevent the impeller from being blocked by dirt particles settling in the sealing gaps, at least one widening is required in the transition area between the blade ring (7) and the hub part (6) on the impeller (4) compared to the sealing gap (10, 11 or 21) Representative slot-like recess (14, 14 or 22) is provided, which extends over the full effective length of the sealing gap (10, 11 or 21).

Description

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

Such a side channel compressor is known from DE-U-87 04 066. In this side-channel compressor, a stripper protruding radially into this sealing gap is arranged in the radial sealing gap section formed between a section of the blade ring projecting laterally beyond the hub part of the impeller and the housing under this section, by means of which a dirt deposit which leads to a blocking of the impeller is to be prevented. It has now been shown that with such a design of a side channel compressor, when the gas is loaded with sticky or moist dirt particles, a blocking of the impeller by dirt particles deposited in the sealing gap is prevented, but not if the gas to be conveyed is fluffy or fibrous Dirt particles is loaded.

The object of the invention is therefore to design a side channel compressor according to the preamble of claim 1 so that even when pumping gases loaded with fluff or fibrous particles, a blocking of the impeller due to a deposition of these particles in the sealing gap is prevented.

The problem is solved by the features specified in the characterizing part of claim 1. Due to the slot-like recesses, a circumferential connection between the side channel and the cavity existing between the hub part and the housing flows through the leakage gas comparatively quickly. In the area of the outlet opening of the side channel The leakage gas flows more densely from the side channel into this cavity and in the region of the inlet opening from the cavity back into the side channel. The dust particles are discharged via this quickly flowed connection. Dirt particles that are deposited in the sealing gap are removed by the edges of the slot-like recess before they lead to a complete clogging of the sealing gap and thus to a blocking of the impeller.

In the case of a dual-flow design of the side channel compressor, slot-like recesses are provided on both sides of the impeller, which are offset from one another in the circumferential direction in order to avoid an impermissible reduction in the mechanical strength of the impeller.

In the case of a side channel compressor in which the blade ring projects beyond the hub part laterally on at least one side in the direction of the axis of rotation and the housing at least partially engages under the portion of the blade ring projecting laterally beyond the hub part to form a radial sealing gap section, to which radial sealing gap section an axial sealing gap connects, clogging of the two sealing gap sections is prevented by the fact that a slot extending continuously to the radial sealing gap section is provided at the bottom of at least one blade cell delimited by two blades, to which a slot groove extending on the hub part parallel to the axial sealing gap section is connected.

A possible clogging of the slot-like recesses themselves is counteracted by the fact that at least one depression in the circumferential direction extending at a multiple of the slot groove width is formed on the housing at least in the area of the axial sealing gap section.

• FIG 1 einen vergrößerten Teilschnitt eines Seiten­kanalverdichters,
• FIG 2 einen Teilschnitt einer anderen Ausführungsform eines Seitenkanalverdichters,
• FIG 3 ein Laufrad des in FIG 1 dargestellten Seiten­kanalverdichters in Draufsicht,
• FIG 4 eine Draufsicht einer Gehäusehälfte des in FIG 1 dargestellten Seitenkanalverdichters.

Based on an exemplary embodiment shown in the drawing the subject of the application is described in more detail below. It shows:

• 1 shows an enlarged partial section of a side channel compressor,
• 2 shows a partial section of another embodiment of a side channel compressor,
• 3 shows an impeller of the side channel compressor shown in FIG. 1 in a top view,
• 4 shows a plan view of a housing half of the side channel compressor shown in FIG.

With 1, the housing of a side channel compressor consisting of two housing halves 2 and 3 is designated. In the housing 1, an impeller 4 is rotatably mounted by means of a shaft 5 which can be coupled to a drive, not shown in the drawing. The impeller of the side channel compressor shown in FIG. 1 consists of a disc-shaped hub part 6 and a blade ring 7 arranged on its outer circumference. The blade ring 7 has a greater width than the hub part 6, so that it is on both sides in the direction of the axis of rotation of the impeller 4 towered over. The two housing halves 2 and 3 are designed such that they engage under the laterally projecting sections of the blade ring 7. The dimensions of the housing halves 2 and 3 are made with respect to the impeller 4 so that between the laterally projecting section 8 of the blade ring 7 and the engaging part 9 of the housing halves 2 and 3 there is a radial sealing gap section 10 and, relative to the hub part 6, an axial sealing gap section 11 consists. This ensures contactless rotation of the impeller 4 relative to the housing halves 2 and 3.

There are blade cells 13 between the individual blades 12 of the blade ring 7. At the bottom of a plurality of such blade cells 13 there is a slot 14 which extends all the way to the radial sealing gap section 10. This Slot continues on the hub part 6 in a slot groove 15 running parallel to the axial sealing gap section. A connection between the side channel 16 of the side channel compressor and the cavity 17 existing between the hub part 6 and the two housing halves 2 and 3 of the housing 1 is thus created via the slot 14 and the slot groove 15. In the case of an impeller 4 of double flow, such slots 14 and slot grooves 15 are provided on both sides of the impeller 4, as is indicated by the broken line in FIG. 3. The slots 14 and slot grooves 15 on both sides of the impeller 4 are circumferentially offset from one another in order to avoid an impermissible weakening of the mechanical strength of the impeller 4.

Because of the pressure difference existing between the area adjacent to the outlet opening 18 and the area adjacent to the inlet opening 19, there is a leakage flow via the sealing gap sections 10 and 11, which is directed from the area adjacent to the outlet opening 18 to the area adjacent to the inlet opening 19 . In the area of the outlet opening 18, leakage gas thus flows from the side channel 16 into the cavity 17, which in the area of the inlet opening 19 flows back into the side channel 16 from the cavity 17.

A larger leakage current can form via the slots 14 and the slot groove 15, which effectively represent an expansion of the sealing gap sections 10 and 11. This leads to a higher flow rate of the leak gas. As a result, lint-like or fiber-like dirt particles which have entered the cavity 17 are conveyed back into the side channel 16 through the slot groove 15 and the slot 14 in the region of the inlet opening 19.

Dirt particles that are deposited in the radial and axial sealing gap sections 10 and 11 are removed by the edges of the slots 14 and slot grooves 15 and from which the sealing gap sections 10 and 11 flowing through leakage current. Thus, such deposits cannot lead to a complete blockage of the sealing gap sections 10 and 11 and thus to a blocking of the impeller 4.

In order to prevent dirt deposits in the slots 14 and slot grooves 15 themselves and thus to prevent them from becoming blocked, depressions 20 are formed on the housing halves 2 and 3 in the region of the axial sealing gap section 11. Such depressions are only shown on the housing half 2 in the drawing. These depressions 20 extend in the radial direction approximately over the radial length of the slot grooves 15 and in the circumferential direction by a multiple of the width of the slot grooves 15. Through the depressions 20 a swirling of the leakage flow is achieved in the slot grooves 15 and thereby a deposit of dirt particles prevented. This swirling action also affects the depressions 20 and thus also prevents dirt particles from being deposited in these depressions 20. Advantageously, the depressions 20 are round, so that they can be produced easily.

2 shows another embodiment of a side channel compressor, in which the blade ring 7 of the impeller 4 and the housing halves 2 and 3 do not overlap. In the transition area between the blade ring 7 and the hub part 6 of the impeller 4 there is therefore only one axial sealing gap 21. On the impeller 4, a groove 22 running parallel to the axial sealing gap 21 is provided in this transition area. This groove 22 fulfills the same functions as the slots 14 and slot grooves 15 provided in the exemplary embodiment according to FIG. 1. Also in this other embodiment of the side channel compressor, several grooves 22 on both sides of the impeller and also depressions 20 in can be distributed over the circumference of the impeller 4 the wall of the housing halves 2 and 3 may be provided.

Claims (4)

1. side-channel compressor with an impeller (4) rotatably mounted in its housing, which consists of a blade ring (7) arranged on a disk-shaped hub part (6) and on the outer circumference of this hub part (6), in which compressor in the transition area from the blade ring (7 ) and hub part (6) a sealing gap (10, 11; 21) is provided,
characterized in that in the transition area between the blade ring (7) and the hub part (6) on the impeller (4) there is at least one slot-like recess (14, 15 or 22) which represents an expansion relative to the sealing gap (10, 11 or 21) which extends over the full effective length of the sealing gap (10, 11 or 21). 2. side channel compressor according to claim 1,
characterized in that, in the case of a double-flow design of the compressor, slot-like recesses (14, 15 and 21) are provided on both sides of the impeller (4), which are offset with respect to one another in the circumferential direction. 3. Side channel compressor according to claim 1 or 2, wherein the blade ring (7) projects beyond the hub part (6) at least on one side in the direction of the axis of rotation and the housing (1) the portion (8) of the hub part (6) laterally projecting The blade ring (7) engages at least partially under the formation of a radial sealing gap section (10), to which radial sealing gap section (10) an axial sealing gap section (11) connects,
characterized in that at the base of at least one blade cell (13) delimited by two blades (12) there is a slot which extends continuously to the radial sealing gap section (10) and on which there is a slot on the hub part (6) parallel to the axial sealing gap section (11) extending slot groove (15) connects. 4. side channel compressor according to claim 1, 2 or 3,
characterized in that at least one depression (20) extending in the circumferential direction by a multiple of the width of the slot groove (15) is formed on the housing (1) at least in the region of the axial sealing gap section (11).

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