EP3728860A1

EP3728860A1 - Side channel blower, in particular secondary air blower for an internal combustion engine

Info

Publication number: EP3728860A1
Application number: EP18716283.9A
Authority: EP
Inventors: Alexander Gotter; Thomas Rösgen; Petra DEITER; Alpay CAPAN; Krischan VON DER BEEK; Matthias Boutros-Mikhail
Original assignee: Pierburg GmbH
Current assignee: Pierburg GmbH
Priority date: 2017-12-21
Filing date: 2018-04-10
Publication date: 2020-10-28
Anticipated expiration: 2038-04-10
Also published as: EP3728860B1; WO2019120633A1; CN111406155B; CN111406155A

Abstract

Side channel blowers having devices for minimizing noise emissions are known, but are often not adequate and limit the volumetric flow to be delivered, or have low efficiency. For that reason, what is proposed is a side channel blower in which the first and the second lateral edges (64, 66) span a first plane E₁ which, together with a second plane E₂ that is spanned by the ejection opening (60), encloses an angle α ≥ 30°, such that the outlet opening (62) extends into the radially bounding wall (33). An embodiment of this kind substantially increases the efficiency and the maximum volumetric flow to be delivered.

Description

Side channel blower, in particular secondary air blower for an internal combustion engine

The invention relates to a side channel blower, in particular secondary air blower for an internal combustion engine with a multi-part housing that at least a first housing part, which is designed as a cup part and a second housing part, which is designed as a lid part, wherein the cup part and the lid part in a parting plane below Intermediate switching of a sealing member are connected to each other and include a blower chamber, wherein an inlet, which opens via an inlet region in at least one substantially annularly extending conveying channel with a radially bounding wall, and an outlet, an impeller, which is drivable via a drive unit is rotatably mounted in the housing and having conveying blades, which cooperate with the opposite conveying channel, and an interruption area between the inlet and the outlet, in which the at least one conveying channel in the circumferential direction un wherein the outlet has an outlet channel portion into which the at least one delivery channel opens, the outlet channel portion having an outwardly directed discharge opening and an outlet opening directed to the delivery channel having first and second side edges, the first side edge being part of the interruption region and the second side edge is part of the radially delimiting wall.

Side channel blowers or pumps are well known and described in a variety of applications. In the motor vehicle, for example, they serve to convey fuel or to inject secondary air into the exhaust system. The drive is usually via an electric motor that drives the impeller. The impeller is formed at its periphery substantially such that it forms a circumferential vortex channel with the axially opposite conveying channel. From the vortex channel forming part of the impeller projecting blades projecting vertically in the direction of opposite, formed in the housing part of the conveying channel, so that pockets are formed between the conveying blades. The pumped fluid in the pockets undergoes an acceleration in the circumferential direction and in the radial direction during rotation of the impeller by the conveyor blades, so that in the conveyor channel, a circumferential vortex flow is formed.

There are side duct blowers are known in which only one conveyor channel is formed on one axial side of the impeller in a housing part, as well as side channel blower in which a delivery channel is formed on both axial sides of the impeller, then both conveyor channels are fluidly connected. In such a side channel blower one of the conveying channels is formed in a cover serving as a housing part, while the other conveying channel is formed in the housing part to which usually the drive unit is attached to the shaft of which the impeller is arranged at least rotationally fixed.

In order to obtain the best possible promotion or pressure increase, it is necessary to use as large a part of the circumference of the conveyor channel. For this reason, the inlet and the outlet have to be as far apart as possible over the circumference in the running direction of the impeller, whereby a short-circuit flow between the inlet and the outlet is to be prevented by an interruption area. A problem with such side channel blowers, the high noise has been found, which arises in particular by pulsations that occur due to sudden pressure surges of the extracted air.

These pressure surges occur, inter alia, immediately after sweeping each bucket at the beginning of the break region, since in the pockets between the bucket still compressed air is present, which was not completely ejected through the outlet, which are accelerated when reaching the interruption area suddenly against the walls , This leads to significantly increased noise emissions.

In order to avoid this, DE 10 2009 006 652 proposes a pump for conveying fluids, the outlet opening of the outlet in special way to shape. However, it has been found that, despite the reduction in pressure surges and, associated with this, a reduction in noise emissions, efficiency is still too low. It would also be desirable to increase the maximum possible throughput.

It is therefore the object to provide a side channel blower with which the above-mentioned disadvantages can be avoided in a simple and cost-effective manner. This object is achieved by the characterizing part of the main claim. In the radially inner region of the impeller, the fluid flows between the blades and leaves the pockets between the impeller blades in the radially outer region. Characterized in that the first and the second side edge span a first plane, which forms an angle a> 30 ° with a second plane, which is spanned by the ejection opening, such that the outlet opening extends into the radially delimiting wall, is a genuine Tangential flow in the transition region from the delivery channel to the outlet channel section of the outlet possible. As a result, the efficiency is basically increased and also higher operating pressures are possible.

Advantageously, the parting plane extends in height or below a bottom surface of the conveying channel in the cover part, whereby the outlet channel section can be made larger on average, which in turn allows an increase in the throughput. In this case, the dividing plane can advantageously extend in steps and the sealing member can be formed as a liquid seal in a groove. In this way it is ensured that no sealing material enters the fan room.

A particularly easy to manufacture arrangement results from the fact that the lid part adjoins the drive unit. Here, an opening for a bearing of a drive shaft is provided in the cover part. The cup part then closes the side channel blower to the outside. Thus, a side channel blower is provided in which the efficiency and the maximum achievable throughput can be substantially increased compared to known side channel blowers. An embodiment of a side channel blower according to the invention is shown in the drawings and will be described below.

Figure 1 shows a side view of a side channel blower in a sectional view.

FIG. 2 shows a perspective view of a cup part of the side channel pump of FIG. 1.

FIG. 3 shows a top view of the cup part of the side channel pump of FIG. 1.

The side channel blower shown in Figure 1 consists of a two-part housing 2 and a rotatably mounted in the housing 2 and driven by a drive unit 3 impeller 4, for example for the promotion of air. The air passes via an axial inlet 6 into an inlet region 8 (see FIG. 2) of a first housing part 10, which in the present embodiment serves as a cup part of the side channel blower. From the inlet region 8, the air then flows into two substantially annularly extending conveying channels 12, 14, of which the first conveying channel 12 is formed in the cover part 10 and the second conveying channel 14 in a second housing part 16, which in the present embodiment as a cover part of the side channel serves, is trained. The cup part 10 and the lid part 16 thus include a fan chamber 17 a.

The cover part 16 has a central opening 15, in which a bearing 18 of a drive shaft 19 of the drive unit 3 is arranged, on which the impeller 4 is fixed. The outlet of the air via a tangential outlet 20, which is arranged on the first housing part 10.

The impeller 4 is disposed between the pot member 10 and the lid member 16 and has at its periphery on conveying blades 22 which are curved and extending radially, wherein the conveying blades 22 are divided by a radially extending peripheral ring 24 in a first row axially opposite to the first conveying channel 12 and a second row axially opposite to the second conveying channel 14, so that two swirl ducts are formed, each by one of Delivery channels 12, 14 are formed with the facing part of the impeller 4. The outer diameter of the delivery channels 12, 14 is slightly larger than the outer diameter of the impeller 4, so that a fluidic connection between the two delivery channels 12, 14 outside the

Outside circumference of the impeller 4 is made so that an exchange of air between the two delivery channels 12, 14 can take place. Between the extending from the peripheral ring 24 blades 22 thus radially outwardly open pockets 26 are formed, in which the air is promoted or accelerated so that the pressure over the length of the conveyor channels 12, 14 is increased.

In order to obtain the best possible delivery rate and pressure increase, the axial inlet 6 is as far as possible from the tangential outlet 20 in the direction of rotation of the impeller 4. In order reliably to prevent a short-circuit flow against the direction of rotation of the impeller 4 from the inlet 6 to the outlet 20, known interruption areas 28 on the cup part 10 and on the lid part 16 are provided between the inlet 6 and the outlet 20. In the drawing, however, only the interruption region 28 in the pot part 10 is shown in FIG. In the interruption regions 28, therefore, the smallest possible gap exists axially opposite the conveying blades 22 of the impeller 4. A further interruption region 32 is formed on a radially delimiting wall 33 of the first housing part 10 and interrupts a radially outer connection region 35 between the two conveying channels 12, 14. The pot member 10 is fastened via not shown screws on the second cover part 16, which by corresponding Holes 34 are inserted, which are formed on radially outwardly extending projections 36 on the cup portion 10. The cover part 16 is in turn connected in a known manner with a housing part 38 of the drive unit 3. Radially behind a wall 40 of the conveying channel 16, a groove 42 in the amount of a bottom surface of the conveying channel 14 is formed. A parting plane 46 of the cup part 10 and the lid part 16 is stepped in this way. Thus, a liquid seal 48 may be provided in the groove 42 for sealing between pot portion 10 and lid portion 16, since the liquid seal 48 has no direct connection to the fan chamber 17.

Radially in front of a wall 50 of the conveying channel 12, an annular web 52 is formed which engages after assembly of the fan in a corresponding groove 54 of the impeller 4, whereby a seal from the conveying channel 12 in the direction of the interior of the impeller 4 takes place. In addition, the cup part 10 has a cylindrical recess 56 into which the drive shaft 19 of the drive unit 3 protrudes. As already known from the prior art, the outlet 20 has a tangential outlet channel section 58, which opens outward into an ejection opening 60. The delivery channels 12, 14 are fluidly connected to the outlet channel section 58 via an outlet opening 62. According to the invention, it is now provided that a first and a second side edge 64, 66 define a first plane Ei which, with a second plane E ₂ , which is spanned by the ejection opening 60, has an angle a> 30 °, in this case approximately 57 °, includes (see in particular Figure 3). This has the consequence that the outlet opening 62 extends far into the radially delimiting wall 33 and thus a "real" tangential outflow can be realized with high efficiency. <br/><br/> In a particularly simple way, at least the pot part 10 can be produced from a duroplastic material as a workpiece-falling workpiece.

However, it should be clear that various modifications of the side channel blower described in the embodiment are possible without departing from the scope of the main claim. In particular, it can be a pump with only one side channel, or the outlet opening and interruptor shape can be configured correspondingly both with respect to the larger current leading to the inlet-facing channel and to the opposite channel.

Claims

PATENT APPLICATIONS

1. Side channel blower, in particular secondary air blower for an internal combustion engine with

a multi-part housing (2), that at least a first housing part (10), which is designed as a cup part and a second housing part (16), which is designed as a cover part, wherein the cup part (10) and the cover part (16) in a parting plane (46) with the interposition of a sealing member (48) are interconnected and include a fan chamber (17),

an inlet (6),

which opens via an inlet region (8) into an at least one substantially annularly extending conveying channel (12, 14) with a radially delimiting wall (33),

and an outlet (20) are formed,

an impeller (4) which is drivable via a drive unit (3), is rotatably mounted in the housing (2) and has conveying blades (22) which cooperate with the opposite conveying channel (12, 14), and an interrupting region (28, 32 ) between the inlet (6) and the outlet (20), in which the at least one conveying channel (12, 14) is interrupted in the circumferential direction, wherein

the outlet (20) has an outlet channel section (58) into which the at least one delivery channel (12, 14) opens, wherein the

Outlet passage section (58) has an outwardly directed discharge opening (60) and a to the delivery channel (12, 14) directed

An outlet opening (62) having first and second side edges (64, 66), the first side edge (64) being part of the discontinuity area (32) and the second side edge (66) being part of the radially delimiting wall (33),

characterized in that

the first and second side edges (64, 66) span a first plane Ei, having a second plane E ₂ passing through the ejection opening (60) is clamped at an angle a> 30 °, such that the outlet opening (62) extends into the radially delimiting wall (33).

2. Side channel blower, in particular secondary air blower for an internal combustion engine according to claim 1,

characterized in that

the parting plane (46) extends in height or below a bottom surface of the conveying channel (14) in the cover part (16).

3. Side channel blower, in particular secondary air blower for an internal combustion engine according to claim 2,

characterized in that

the parting plane (46) extends in steps and in a groove (42), the sealing member (48) is formed as a liquid seal.

4. Side channel blower, in particular secondary air blower for a

Internal combustion engine according to one of the preceding claims, characterized in that

the lid part (16) adjoins the drive unit (3).

5. Side channel blower, especially secondary air blower for a

Internal combustion engine according to one of claims 1 or 2,

characterized in that

at least the cup part (10) is made of a thermosetting plastic as a workpiece falling workpiece.