EP1803940A1 - Regenerative pump - Google Patents

Abstract

The fluid conveyancing system comprises a housing (12) with a rotary axis (A) that has a ring-like extending conveyance channel (14) as well as an inlet opening (34) to a suction region (32) of the conveyance channel and an outlet opening (38) from a compression region (36) of the conveyance channel.

Description

The present invention relates to a fluid delivery device, in particular a side channel blower, as it can be used for example for conveying combustion air in a vehicle heater.

Such a fluid delivery device generally has a ring-like delivery channel in a housing, which receives the medium to be conveyed in a suction region, ie, sucks it, and then discharges this medium in an ejection region. Between the suction area and the discharge area, an interrupting area is provided in order to be able to ensure that the pressure gradually built up when the fluid flows along the conveying channel can also be maintained. The delivery channel is covered by a delivery wheel, which is driven by a generally fixed to the housing or possibly partially through this housing provided with drive motor for rotation. For this purpose, the housing has an opening in which a drive shaft of the drive motor extends. In the region of this opening, a sealing arrangement is generally provided, which serves to prevent escape of the medium to be conveyed through this opening. This seal arrangement provides a sealing effect between the drive shaft rotating in operation and the housing to be regarded as stationary. This places considerable demands on this seal arrangement. On the one hand, given material resistance to the medium to be promoted, it should, of course, be able to seal against it. Due to the speeds involved, this naturally leads to considerable frictional effects, which not only entail energy losses, but can also lead to leaks, especially after a prolonged service life and the occurrence of wear. Such leaks are undesirable not only because, especially when the medium to be delivered is a liquid, they may have the functionality of the drive motor dangerous losses. Also, thereby the pressure build-up in the region of the conveyor channel is weakened with corresponding impairment of the delivery efficiency.

As here usable seal assemblies various structural designs are known. Thus, in particular, when liquids are to be promoted, shaft seals, mechanical directions or Wälzkörperlager be used with gaskets. In this context, it should be noted that, of course, such a sealing arrangement can also take over the functionality of the bearing and thus support the drive shaft, so that a both the storage function and the sealing function accepting module can be used here. In order to reduce the wear occurring in such arrangements, it is known to provide lubricant or to use the liquid medium to be pumped as a lubricant. If the medium to be pumped gas, so for example, labyrinth seals are used, which are less subject to the problem of wear, as the problem of pressure leaks.

It is the object of the present invention to provide a fluid delivery device, in particular side channel blower, in which the leaks or pressure losses occurring during operation can be reduced.

According to the invention, this object is achieved by a fluid conveying device, in particular a side channel blower, for example for a vehicle heater, comprising a housing with a conveyor channel extending around an axis of rotation, wherein an inlet opening leads to a suction region of the conveyor channel and an outlet opening leads away from an ejection region of the conveyor channel and the annular conveying channel between the ejection region and the suction region is interrupted by an interrupting region, a conveying wheel covering the conveying channel and rotatable about the rotational axis, a drive motor having a driving connection with the conveying wheel and in one In the region of the opening there is provided a sealing arrangement providing a sealing effect between the drive shaft and the housing, further comprising a first connection channel arrangement in the housing, which connects between the conveying channel and the region of the opening produces, which is located on the side remote from an engine body side of the seal assembly.

In the case of the fluid delivery device according to the invention, it is ensured by the first connection channel arrangement that, in the region of the opening lying on the motor side of the seal arrangement, the build-up of an overpressure or the accumulation of leaks is largely avoided. The first connection channel arrangement thus provides a pressure relief, which is very efficient, especially when the first connection channel arrangement opens into the delivery channel in the region of the intake region. This has the consequence that due to the fact that in the suction region of the conveying channel generally prevails a pressure which is lower than the ambient pressure, a correspondingly low pressure prevails in the first connection channel arrangement and thus also in that region of the opening, which at the engine facing away Side of the seal lies. Since it can generally be assumed that prevails on the motor side facing the seal in the opening, a pressure which corresponds approximately to the ambient pressure, thus arises over the seal assembly across a pressure gradient, which counteracts escape of the fluid to be delivered through the seal assembly.

In the case of an embodiment that is structurally particularly easy to implement but nevertheless very effective, it can be provided that the first connection channel arrangement comprises at least one connection channel open to an end face of the housing. Alternatively or additionally, it is possible that the first connection channel arrangement at least one in Housing between the opening and the delivery channel extending connection opening comprises. The provision of such a connection opening has the advantage that structuring of an outer surface of the housing produced thereby can be avoided with the risk of producing unwanted noises.

In order to be able to ensure the above-mentioned effect with a pressure difference counteracting the escape of fluid across the seal arrangement, it is proposed that a second connection channel arrangement is provided, which connects the region of the opening to the side of the seal arrangement facing the engine body lies, and the environment manufactures.

Again, it is possible that the second connection channel arrangement comprises at least one opening opening into the opening.

In particular, in the embodiment as a side channel blower can be provided that the delivery channel is formed on an end face of the blower housing and is open in the axial direction. This end face then also lies opposite the delivery wheel in the axial direction, and in particular when the first connection channel arrangement comprises at least one connection channel open to a surface of the housing, then it can likewise be open to this end side.

Fig. 1

eine vereinfachte Axialschnittansicht einer erfindungsgemäß aufgebauten Fluidfördereinrichtung;

Fig. 2

eine perspektivische Ansicht eines Gehäuses einer erfindungsgemäßen Fluidfördereinrichtung mit alternativer Ausgestaltung der ersten Verbindungskanalanordnung.

The present invention will be described below in detail with reference to the accompanying drawings. It shows:

Fig. 1

a simplified axial sectional view of a fluid delivery device constructed according to the invention;

Fig. 2

a perspective view of a housing of a fluid conveying device according to the invention with an alternative embodiment of the first connection channel arrangement.

FIG. 1 shows a fluid conveying device in the form of a side channel blower 10 that can be used, for example, for conveying combustion air for a vehicle heater. This side channel blower 10 comprises a housing 12 produced by casting, for example, from metal, in which a conveying channel 14 which extends in a ring-like manner around a rotation axis A is formed. This delivery channel 14 is open to an axial end face 16 of the housing 12, and this end face 16 is opposite to a rotatable about the axis of rotation A feed wheel 18. Also, the feed wheel 18 has one of the ring-like geometry of the conveyor channel 14 corresponding annular recess 20 with provided therein, in the figure, however, not shown conveying blades. At the side facing away from the end face 16 back 22 of the housing 12 is a generally designed as an electric motor drive motor 24 is provided. This has a drive shaft 26 which passes through a central, so preferably concentric with the axis of rotation A opening 28 in the housing 12. The drive shaft 26 extends into the region of the feed wheel 18 and is rotatably connected thereto. By energizing the drive motor 24, the feed wheel 18 can be rotated in rotation about the axis of rotation A, so that the known conveying effect can be generated. The drive motor 24 comprises a region, generally designated here as the motor body 30, which comprises, for example, the motor housing, the winding region or the armature region also coupled to the drive shaft 26 and the like. Here it is conceivable, for example, that at least parts of this body region 30, that is, for example, parts of the motor housing, are also provided by the housing 12.

In the housing 12 shown in a perspective view in FIG. 2, the conveying channel 14 which is open to the front side 16 can be seen. This has a suction region 32 in which the medium to be delivered, for example air, can enter or be sucked in via an inlet opening 34 , This medium then flows at the generated by the rotation of the feed wheel 18 conveying action along the annular conveying channel 14 to a Discharge region 36 of the conveying channel 14, where it exits through an outlet opening 38 from the conveying channel 14 and to the area to be fed, so for example, the burner region of a vehicle heater, can flow. Between the ejection region 36 and the suction region 32 is an interruption region 35.

Returning again to FIG. 1, it can be seen that in the area of the opening 28 formed in the housing 12, a sealing arrangement, generally designated 40, is provided. This seal assembly 40, which may also have the function of supporting the drive shaft 16, ensures that the escape of the medium to be conveyed via the formed between the feed wheel 18 and the end 16 of the housing 12 gap-like gap 42 and the opening 28 as far as possible prevented. It should be noted that even with only a small amount of space 42, the opening 28, often inevitably in connection with the delivery channel 14 and thus in the space 42 a certain overpressure compared to the ambient pressure can prevail, which then also in the opening 28 would train. Depending on how strong the sealing effect of the seal assembly 40 is, then the risk of leakage across the seal assembly 40 away is more or less large. It should be noted that, depending on the purpose, the drive shaft 26 may have a comparatively high rotational speed in comparison to the case 12 to be regarded as stationary, and thus the sealing arrangement 40 is subject to a correspondingly high mechanical load. Especially after prolonged service life and forcibly occurring wear of such a seal assembly 40 may cause leaks.

In order to counteract this, in the case of the side channel blower 10 shown in FIG. 1, a first connection channel arrangement 44 is provided. In the example shown, this comprises a connection opening 46, which establishes a connection between the delivery channel 14 and the opening 28. In particular, the connection opening 46 opens into the opening 28 in a Area 48 of the same, which is located on the side facing away from the engine body 30, so the end face 16 and the feed wheel 18 facing side 50 of the seal assembly 40. Furthermore, it can be seen that the connection opening 46 opens into the delivery channel 14 in the region of the intake region 32, preferably in that peripheral region in which the inlet opening 35 lies. This means that the connection opening 46 establishes a connection between the region 48 of the opening 28 and the delivery channel 14 in a region in which a lower pressure prevails in the delivery mode than, for example, in the environment, since there is the suction effect, ie a negative pressure is generated in comparison to the ambient pressure. A first effect of this first connection channel arrangement 44 is thus that when, for example, due to the presence of the gap-like intermediate space 42 to be conveyed medium enters the region 48 of the opening 28, this medium due to the first connection channel assembly 44, ie the connecting channel 46, produced Connection to a region of low pressure is withdrawn and passes through the connecting channel 46 in the intake region 32 and thus returned to the delivery circuit.

It can further be seen that a second connection channel arrangement 52 is provided in the housing 12. These also include, for example, a connection opening 54, which opens into a region 56 of the opening 28, which is located on the side facing the engine body 30 and thus facing away from the end face 16 and the feed wheel 18 side 58 of the seal assembly 40. Furthermore, the second connecting channel arrangement 52, that is, in the example shown, the connecting opening 54, for example in a radially outer region of the housing 12 to the environment open. The presence of the second connection channel arrangement 52 thus forcibly ensures that in the region 56 of the opening 28, a pressure prevails which corresponds approximately to the prevailing outside of the side channel blower 10 ambient pressure, regardless of whether or how much the engine body 30 to in capable of that Seal opening 28.

Taking into account or in combination with the above-described effect of the first connection channel arrangement 44, ie the generation of a lower pressure in the region 48 of the opening 28, it is thus forcibly ensured that a pressure gradient arises across the seal arrangement 40, in which on the side 58 of the seal assembly 40, a higher pressure prevails, than on the side 50. A possible over the seal assembly 40 away leakage, available through the design of the seal assembly 40 and / or induced by wear occurring during operation, thus can not result , the fluid passes from the region 48 of the opening 28 in the region 56 of the opening 28. On the contrary, with such permeability of the sealing arrangement 40, a flow from the region 56 into the region 48 and via the first connection channel arrangement 44 into the intake region 32 of the delivery channel 14 will inevitably occur. In particular, if such a structure is used to convey air, this has the consequence that a possibly occurring leak in the region of the sealing arrangement 40 does not result in any impairment of the conveying efficiency. This leakage has only the consequence that a portion of the air entering the suction region 32 of the delivery channel 14 does not flow via the inlet opening 34 but via the second connection channel arrangement 52, the areas 56 and 48 of the opening 28 and the first connection channel arrangement 44 into the suction area 32 flows in. However, the total amount of the inflowing air can be kept constant.

Another significant advantage of this embodiment is that much cheaper and simpler seals can be used, since the risk of escape of medium to be conveyed through the opening 28 can be effectively excluded. This is particularly advantageous if such a seal assembly is to take over the storage function or combined with a bearing assembly or integrated into it.

A modification in the region of the first connection channel arrangement 44 is shown in FIG. It can be seen here the previously mentioned housing 12, in which the first connection channel arrangement 44 now comprises an open to the end face 16 connecting channel 60. This also flows into the intake region 32 of the delivery channel 14 and thus provides a connection between the region 48 of the opening 28 and this intake region 32. In principle, therefore, the same functionality can be obtained here as has already been described above, wherein the provision of the first connection channel arrangement 44 with the connection channel 60 open to the end side 16 can be realized more easily, particularly when produced in a casting method.

It is to be understood that the principles of the present invention may be practiced otherwise than as previously described. For example, the first connection channel arrangement 44 and / or the second connection channel arrangement 52 may comprise more than one connection channel or a connection opening. Also, the area of the mouth of the first connection channel arrangement 44 can be varied in the delivery channel 14 in comparison to the illustrated. Of importance or particular advantage, however, is that taking into account the pressure build-up along the conveying channel 14, the connection with the conveying channel 14 is still in a range in which the prevailing pressure is below the example prevailing in the region 56 of the opening 28 pressure. Any such region or longitudinal section of the delivery channel 14 is still interpreted within the meaning of the present invention as the region associated with the intake region 32. It goes without saying that the flow cross-section of the respective connecting channel arrangements 44, 52 and, of course, the inlet opening 34 can be adapted to the desired pressure conditions to be set. Furthermore, it is of course possible that the second connection channel arrangement 52 may alternatively or in addition to the illustrated connection opening, the motor body 30 itself may include insofar as this flat is not flow sealed, but creates a flow connection between the region 56 of the opening 28 and the environment.

Claims (7)

Fluid delivery device, in particular side channel blower, for example for a vehicle heater, comprising a housing (12) with a about an axis of rotation (A) annularly extending conveying channel (14), wherein an inlet opening (34) to a suction region (32) of the conveying channel (14) and an outlet opening (38) of an ejection region (36) of the conveying channel (14) leads away and the annular conveying channel (14) between the ejection region (36) and the suction region (32) is interrupted by a breaker area (35), the Conveying channel (14) covering and about the axis of rotation (A) rotatable conveyor wheel (18), a drive motor (24) with one with the feed wheel (18) in drive connection and in one of the conveyor channel (14) surrounded opening (28) in the Housing (12) extending drive shaft (26), wherein in the region of the opening (28) has a sealing effect between the drive shaft (26) and the housing (12) providing Dichtungsanord further comprising a first connecting channel arrangement (44) in the housing (12), which establishes a connection between the conveying channel (14) and the region (48) of the opening (28), which is at the of a motor body (30) facing away from side (50) of the seal assembly (40). Fluid delivery device according to claim 1,
characterized in that the first connecting channel arrangement (44) opens into the conveying channel (14) in the region of the suction region (32). Fluid delivery device according to claim 1 or 2,
characterized in that the first connection channel arrangement (44) comprises at least one connection channel (60) open to an end face (16) of the housing (12). Fluid delivery device according to one of claims 1 to 3,
characterized in that the first connection channel arrangement (44) comprises at least one connection opening (46) running in the housing (12) between the opening (28) and the delivery channel (14). Fluid delivery device according to one of claims 1 to 4,
characterized in that a second connecting channel arrangement (52) is provided, which connects between that region (56) of the opening (28) which lies on the side (58) of the sealing arrangement (40) facing the motor body (30), and Environment produces. Fluid delivery device according to claim 5,
characterized in that the second connection channel arrangement (52) comprises at least one opening (54) opening into the opening (54). Fluid delivery device according to one of claims 1 to 6,
characterized in that the conveying channel (14) on an end face (16) of the fan housing (12) is formed and is open in the axial direction.

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