DE102009006652B4 - Side channel blower, in particular secondary air blower for an internal combustion engine - Google Patents

Abstract

There are side channel blowers with devices for minimizing noise emissions known, but which are often not sufficient and limit the volume flow to be funded. Therefore, a side channel blower is proposed in which the at least one delivery channel (12, 14) leads essentially in the tangential direction to the outlet (20), wherein an outlet opening (58) in the radially delimiting wall (33) in the direction of rotation of the impeller ( 4) extends to an outlet edge (62) which projects into the interruption region (28; 30) of the at least one delivery channel (12; 14), in the direction of rotation of the impeller (4) immediately behind the outlet opening (58) at the radially delimiting one Wall (33) has a recess (60) is formed, which reduces the expansion of the interruption region (32) on the radially delimiting wall (33) in the circumferential direction. By such a design, a further noise reduction is achieved, and increases the volume flow delivered.

Description

The invention relates to a side channel blower, in particular secondary air blower for an internal combustion engine having a multi-part housing, in which an axial inlet, which opens into at least one substantially annularly extending conveying channel via an inlet region, and an outlet, an impeller, which via a drive unit is drivable, 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 is interrupted in the circumferential direction.

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 toward the opposite, formed in the housing part of the conveyor channel, so that pockets are formed between the conveyor 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.

To avoid this, is in the DE 100 24 741 B4 proposed a pump for conveying fluids, wherein the outlet is arranged axially to the impeller and the delivery channel opens into an outlet opening whose width is initially smaller in the direction of rotation of the impeller and then in the radially outer region has a small constant width.

By such a design, the noises occurring can indeed be reduced, but the funded fluid flow is further accelerated behind the outlet opening against the breaker area, so that pressure surges arise, which leads to an increased noise emission, since sudden cross-sectional changes behind the interruption area for partial volumes of the pockets in the funded volume when reaching the interruption area arise.

Furthermore, from the US 2005/0220614 A1 a side channel blower known in which one or more circumferentially tapered recesses are arranged for noise reduction in the axial wall surface of the interruption region.

Also is from the US 2,217,211 a blower known in which behind the substantially radial outlet a recess in the radially delimiting side wall is formed, with which the centrifugal force effect is to be overcome.

It is therefore the task of creating a side channel blower with which the noise that occurs can be further reduced.

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. By the tangentially expiring conveyor channel first pass over the Inner sides of the conveyor pockets the interruption region of the conveying channel, so that the inlet cross section steadily decreases upon rotation of the impeller. The compressed fluid can leave the conveyor pockets in the area of the exit without flow obstacles. Also, the fluid, which is still in the pockets and is accelerated in these and possibly has flowed through turbulence in the outer area in the pockets, can leave the pockets on the lying in the direction of rotation behind the conveyor channel region of the outlet and flow without flow obstacles , This prevents pressure surges on the housing and reduces noise emissions. Characterized in that in the direction of rotation of the impeller behind the outlet opening on the radially delimiting wall a recess is formed, which reduces the expansion of the interruption region on the radially delimiting wall in the circumferential direction, an additional relaxation area for the pumped fluid is created behind the outlet opening, in which the still existing pressure increase can be removed from the bag, whereby the pressure pulsations occurring are further reduced.

Preferably, the extension of the outlet opening in the direction of rotation of the impeller increases in the direction of the housing part of the secondary air blower, in which the inlet is formed. By this embodiment, the flow vector of an eddy in the region of the outlet is modeled, whereby an additional emptying of the pockets is achieved.

An additional improvement is achieved in that the length of the projection of the outlet edge delimiting the outlet opening in the direction of rotation of the impeller is at least as great as or greater than the distance between two impeller blades. This will ensure that most of the pressurized fluid is drained from the entire bag to the outlet.

Preferably, the extension of the recess in the direction of rotation of the impeller increases in the direction of the housing part of the secondary air blower, in which the inlet is formed. In this way, additional pressure pulsations are reduced because the relaxation path is increased.

In a further embodiment, the extension of the outlet opening increases in the direction of rotation of the impeller axially towards the inlet of the secondary air blower stronger than the extension of the recess in the direction of rotation, so that an angle between the outlet edge of the outlet opening and an interruptor edge is formed. The air flowing out of the recess changes the pressure of the fluid in the pocket and thus the size of the velocity vector in the circumferential direction. Thus, the direction of the velocity vector of the hurdles changes, which is used here for the best possible emptying of the pockets also behind the inlet opening to reduce the pressure surges.

In a particularly advantageous embodiment of the invention, the housing has two axially opposite conveyor channels, wherein the impeller blades of the impeller facing the conveyor channels to both axial sides of the impeller and the extension of the outlet opening in the direction of rotation of the impeller axially from a peripheral ring of the impeller in the direction of the axial ends of the conveyor blades grows. In this way, the vortex formation of both conveyor channels or both impeller sides is taken into account in the formation of the outlet opening to achieve the best possible emptying of the pockets and thus a large flow rate, the noise emissions continue to decrease by avoiding pressure surges on both axially opposite sides of the ejection area.

Preferably, the extent of the recess in the direction of rotation of the impeller grows axially from the peripheral ring of the impeller toward the axial ends of the impeller blades, whereby the relaxation of the funded fluid is used behind the outlet opening with respect to both conveyor channels for noise reduction.

Thus, a side channel blower is provided in which compared to known side channel blowers the expelled volume flow is increased with the same size of the pump and at the same time outwardly urgent noise due to pressure surges occurring in the region of the outlet and the interruption range are significantly reduced.

An embodiment of a side channel blower according to the invention is shown in the drawings and will be described below.

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

2 shows a perspective view of a housing part of the side channel pump of 1 ,

three shows a perspective view of the cover part of the side channel pump of 1 ,

This in 1 Side channel blower shown consists of a two-part housing 2 and one in the housing 2 rotatably mounted and via a drive unit three driven impeller 4 , for example, for the promotion of air. The air passes via an axial inlet 6 in an inlet area 8th a first housing part 10 which serves in the present embodiment as a cover part of the side channel blower. From the inlet area 8th from the air then flows into two substantially annular extending delivery channels 12 . 14 of which the first conveying channel 12 in the lid part 10 is formed and the second conveying channel 14 in a second housing part 16 is formed, in its central opening 17 also a storage 18 a drive shaft 19 the drive unit three is arranged on the impeller 4 is attached. The exit of the air takes place via a tangential outlet 20 , on the second housing part 16 is arranged.

The impeller 4 is between the lid part 10 and the second housing part 16 arranged and has at its periphery conveyor blades 22 which are curved and extend radially, wherein the conveying blades 22 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 conveyor channel 14 be divided, so that two vortex channels are formed, each through one of the delivery channels 12 . 14 with the facing part of the impeller 4 be formed. 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 outer circumference of the wheel 4 exists, allowing an exchange of air between the two delivery channels 12 . 14 can take place. Between the itself from the peripheral ring 24 extending conveyor blades 22 thus become radially outwardly open pockets 26 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 in the direction of rotation of the impeller 4 as far as possible from the tangential outlet 20 away. To reliably a short-circuit flow against the direction of rotation of the impeller 4 from the inlet 6 to the outlet 20 to stop are between the inlet 6 and the outlet 20 interruption regions 28 . 30 on the lid part 10 and on the housing part 16 arranged, which the delivery channels 12 . 14 interrupt so that in the interruption areas 28 . 30 axially opposite to the conveyor blades 22 of the impeller 4 the smallest possible gap is available. An interruption area 32 is on a radially bounding wall 33 of the second housing part 16 formed and interrupts a radially outer connection region 35 between the two delivery channels 12 . 14 ,

In the 2 and three you can see that in the lid part 10 and in the second housing part 16 arranged conveyor channels 12 . 14 have a substantially constant width and with the exception of the interruption areas 28 . 30 over the circumference of the lid part 10 and the housing part 16 extend. At the in 2 Thus selected view rotates the impeller 4 counterclockwise from the inlet area 8th until the end of the delivery channel 12 and then over the interruption area 28 back to the inlet area 8th ,

The lid part 10 is via screws on the second housing part 16 attached, which through corresponding holes 34 be plugged, which in itself radially outwardly extending projections 36 on the lid part 10 are formed. At two of these projections 36 There are also small, axially extending bolts 38 , which for prefixing the cover part 10 on the second housing part 16 serve, at the appropriate holes 40 are formed.

Radially behind a wall 42 of the conveyor channel 12 is a groove 44 formed in the for sealing between the cover part 10 and second housing part 16 a sealing ring 46 is inserted, which over noses 48 in the groove 44 is held.

Radial in front of a wall 50 of the conveyor channel 12 is an annular bridge 52 formed after the assembly of the blower in a corresponding groove 54 of the impeller 4 engages, creating a seal from the delivery channel 12 towards the interior of the wheel 4 he follows. In addition, the cover part 10 a cylindrical recess 56 on, in which the drive shaft 19 the drive unit three protrudes.

According to the invention, the delivery channels 12 . 14 in the lid part 10 and in the housing section 16 designed so that they are in the area in front of the outlet 20 instead of as previously in the circumferential direction from here towards the outlet 20 like the outlet 20 extend in the tangential direction. At the same time, the width of the delivery channels 12 . 14 less than the width of the outlet 20 so this one from the delivery channels 12 . 14 is initially flowed only over its radially outer region. An outlet opening 58 passing through the radially delimiting wall 33 of the second housing part 16 leads and the inside of the fan with the outlet 20 connects, is formed such that in the direction of rotation of the impeller 4 the outlet opening 58 into the interruption areas 28 . 30 the housing parts 10 . 16 extends, as in 2 can be seen.

In the embodiment shown here, an outlet edge extends 62 which the outlet opening 58 in the direction of rotation of the impeller 4 limited, from an inner edge 64 of the conveyor channel 14 in the second housing part 16 on the wall 33 obliquely upwards, ie with an axial component in the direction of the cover part 10 and a component in the direction of rotation of the impeller 4 , The angle of this slope should be chosen so that the component in the circumferential direction at least the distance between two conveyor blades 22 equivalent.

In addition to this particular shape of the outlet opening 58 is immediately behind the outlet opening 58 a recess 60 at the interruption area 32 the radially delimiting wall 33 formed. This recess 60 is through a breaker edge 66 in the direction of rotation of the impeller 4 limited, which also from the bottom of the housing part 16 extends obliquely upwards, ie an axial component in the direction of the cover part 10 and a component in the direction of rotation of the impeller. The breaker edge 66 and the outlet edge 62 however, are not parallel but are at an angle to each other, with the outlet edge 62 the component is larger in the direction of rotation than for the breaker edge 66 , It should be noted that with a larger distance between the conveyor blades 22 of the impeller 4 also the included angle between the breaker edge 66 and the outlet edge 62 should be chosen larger.

Now consider the movement of an individual to the lid part 10 attentive bag 26 in the outlet area of the impeller 4 which due to the arrangement of the inlet 6 has a higher filling than the axially opposite pocket 26 , so this first passes over the interruption area with its radially inner edge 28 of the lid part 10 , Upon further rotation of the impeller 4 will the bag 26 from inside to outside through the interruption area 28 covered, so that only a significantly reduced proportion of air can flow back into the bag. Before the bag 26 completely through the interruption area 28 is covered, the bag reaches the outlet opening 58 so that the compressed air can flow out. With reaching the end of the delivery channel 12 However, there is still compressed air in the bag 26 of the impeller 4 present the bag 26 leaves at its radial outer edge. The velocity vector of this residual air has a component radially outward, a component in the direction of rotation of the impeller 4 and a component toward the lid part 10 , In this case, the component of the air flow in the circumferential direction substantially corresponds to the speed component of the impeller 4 , It follows that due to the selected maximum extent of the outlet opening 58 in the direction of rotation out of the bag 26 escaping air not against the outlet edge 62 the outlet opening 58 in the form of a pressure surge strikes, but in the outlet 20 flows.

The behind the outlet opening 58 escaping air also does not strike immediately against the break area 32 on the radial wall 33 but flows into the recess 60 , where at least a slight relaxation takes place by turbulence of the air reaching into the recess. The angle is chosen so that neither over the entire height of the bag 26 simultaneously ejected air flow the breaker edge 66 At the same time, the airflow simultaneously discharged over the entire width is reached. At the same time, the expansion path for the existing residual air increases. So pressure surges can be additionally reduced.

The described side channel blower is characterized by a significant reduction in noise emissions compared to known side channel blowers. At the same time, a high delivery rate is achieved.

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, this may be a pump with only one side channel, or the outlet opening and interruptor shape may be configured correspondingly both with respect to the inlet channel leading to the larger current and to the channel opposite to it. In this case, it would be necessary to design the outlet opening with two bevels, which expand the outlet opening from the height of the peripheral ring upwards and downwards accordingly.

Claims (7)

Side channel blower, in particular secondary air blower for an internal combustion engine with a multi-part housing, in which an axial inlet, which opens via an inlet region in at least one substantially annularly extending conveying channel, and an outlet, an impeller, which is drivable via a drive unit, is rotatably mounted in the housing and has 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 is interrupted in the circumferential direction, characterized in that the at least one conveying channel ( 12 ; 14 ) substantially in the tangential direction to the outlet ( 20 ), wherein an outlet opening ( 58 ) in the radially delimiting wall ( 33 ) in the direction of rotation of the impeller ( 4 ) to an outlet edge ( 62 ) extending into the interruption area ( 28 ; 30 ) of at least a conveyor channel ( 12 ; 14 ), wherein in the direction of rotation of the impeller ( 4 ) immediately behind the outlet opening ( 58 ) on the radially delimiting wall ( 33 ) a recess ( 60 ) is formed, the extension of the interruption area ( 32 ) on the radially delimiting wall ( 33 ) reduced in the circumferential direction. Side channel blower, in particular secondary air blower for an internal combustion engine according to claim 1, characterized in that the extension of the outlet opening ( 58 ) in the direction of rotation of the impeller ( 4 ) in the direction of the housing part ( 10 ) of the secondary air blower, in which the inlet ( 6 ) is formed, grows. Side channel blower, in particular secondary air blower for an internal combustion engine according to one of claims 1 or 2, characterized in that the length of the projection in the direction of rotation of the impeller ( 4 ) the outlet opening ( 58 ) limiting outlet edge ( 62 ) is at least as large as or greater than the distance between two conveying blades ( 22 ) of the impeller ( 4 ). Side channel blower, in particular secondary air blower for an internal combustion engine according to claim 1, characterized in that the extension of the recess ( 60 ) in the direction of rotation of the impeller ( 4 ) in the direction of the housing part ( 10 ), in which the inlet ( 6 ) of the secondary air blower is growing. Side channel blower, in particular secondary air blower for an internal combustion engine according to claim 4, characterized in that the extension of the outlet opening ( 58 ) in the direction of rotation of the impeller ( 4 ) axially towards the inlet ( 6 ) of the secondary air blower grows more than the extent of the recess ( 60 ) in the direction of rotation, so that an angle between the outlet edge ( 62 ) of the outlet opening ( 58 ) and a breaker edge ( 66 ) is trained. Side channel blower, in particular secondary air blower for an internal combustion engine according to one of the preceding claims, characterized in that the housing ( 2 ) two axially opposite conveyor channels ( 12 . 14 ), wherein the conveying blades ( 22 ) of the impeller ( 4 ) to both axial sides of the impeller ( 4 ) the funding channels ( 12 . 14 ) and the extension of the outlet opening ( 58 ) in the direction of rotation of the impeller ( 4 ) axially from a peripheral ring ( 24 ) of the impeller ( 4 ) towards the axial ends of the conveyor blades ( 22 ) grows. Side channel blower, in particular secondary air blower for an internal combustion engine according to claim 6, characterized in that the extension of the recess ( 60 ) on the housing ( 2 ) in the direction of rotation of the impeller ( 4 ) axially from the peripheral ring ( 24 ) of the impeller ( 4 ) towards the axial ends of the conveyor blades ( 22 ) grows.

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