DE102014208128A1 - Radial fan with improved overflow edge geometry - Google Patents

Abstract

A radial fan, in particular for a vacuum cleaner, comprises an impeller (2) rotatable about an axis of rotation (9) and drivable by a motor, which has a plurality of blades (7) for producing an at least partially radially outward air flow, and a stationary impeller Guiding device (3) having a perpendicular to the axis of rotation (9) adjacent to the impeller (2) arranged diffuser plate (48) surrounding this radially outwardly annular wall (14) and the impeller (2) at least partially enclosing hood (21), wherein between the hood (21), the impeller (2) and the diffuser plate (48) a continuous annular space (23) surrounding the impeller (2) is formed, wherein between an outer edge of the diffuser plate (48) and the annular wall ( 14) a plurality of openings (50) is formed, which allow an air passage from the annular space (23) to the impeller (2) opposite side of the diffuser plate (48), wherein the outer edge of the Di Fuser plate (48) in the region of each opening (50) at least one flowed edge portion (34) and at least one overflowed edge portion (49), and wherein the at least one overflowed edge portion (49) has a portion (46), which is a circular arc, whose center lies on the axis of rotation (9) is formed. As a result, a radial fan is provided in which a higher aerodynamic efficiency and / or a reduction of the total sound power level are made possible.

Description

Field of the invention

The invention relates to a radial fan, in particular a radial fan for a vacuum cleaner, which comprises a rotatable about a rotation axis, driven by a motor impeller having a plurality of blades for generating an at least partially radially outward air flow, and a fixed Nachleiteinrichtung, the a perpendicular to the rotational axis axially adjacent to the impeller arranged diffuser plate, this radially outwardly surrounding annular wall and the impeller at least partially enclosing hood, wherein between the hood, the impeller and the diffuser plate, the impeller radially outer surrounding, continuous annular space is formed.

Background of the invention

The task of a blower, especially in vacuum cleaners, is to provide a suction power as a product of negative pressure and volume flow. Vacuum cleaners usually use radial fans. Such a radial fan comprises a drive motor, in particular an electric motor, and an aerodynamic device, which comprises a radial impeller and a guide device. The air volume flow to be delivered typically flows axially into the impeller which produces an at least partially radially outwardly directed air flow, i. an air flow whose flow direction has a radially outwardly directed component. As a rule, the flow direction when leaving the impeller also has a directed in the direction of rotation of the impeller tangential component. The Nachleiteinrichtung serves to deflect the generated air flow in a desired direction. Since the electric drive motor usually has to be cooled, the generated air flow is usually deflected in such a way that components of the electric motor can flow through and be cooled. In the Nachleiteinrichtung therefore takes place in particular a deflection of the air flow generated by the impeller of an obliquely outwardly directed, at least partially radial direction in an axial direction, usually being returned to the cooling of the engine, the air flow from a periphery of the impeller in the vicinity of the drive axle becomes. In the course of the air flow usually flows out of the fan in the axial direction. The Nachleiteinrichtung also serves the pressure recovery and is therefore often referred to as a diffuser.

It is known that a Nachleiteinrichtung for a radial fan is designed as a plate diffuser. In this case, a substantially circular plate is arranged parallel to a disc-shaped base plate of the impeller, which is arranged perpendicular to the axis of rotation, at a small distance to the base plate, which is also referred to as a diffuser plate. The impeller is enclosed by a hood, which delimits it against the environment, leaving a gap between the hood and the periphery of the impeller. The outer diameter of the diffuser plate is larger than the outer diameter of the impeller, so that between the periphery of the impeller, the diffuser plate and the hood results in an annular space in which the air flow is conveyed through the blades of the stator. In the annulus guide vanes may be arranged, which interrupt the annulus and lead the exiting air from the impeller. But the annulus can also be empty, wherein in the diffuser plate a plurality of openings is provided, through which the air conveyed by the impeller can pass to the impeller opposite side of the diffuser plate, where means for further guidance of the air flow, for example in the axial direction and / or arranged radially inward.

Out EP 0 773 620 B1 For example, a motor housing is known which has a circulation fan mounted on the motor shaft and a deflecting means to guide the air flow emitted by the fan via the motor. The deflection means has a baffle plate which has a plurality of openings at its outer edge. The openings are bounded by curved wall parts and open into air inlet openings, through which the air flow passes into an air chamber on the other side of the diffuser plate. The air inlet openings have an edge streamed by the air flow, which is directed essentially in the radial direction.

According to JP H11-206630 A In the case of an electric blower, a substantially disc-shaped diffuser is provided which has openings at its circumference through which the air flow generated by the impeller of the blower can pass to the other side of the diffuser. These openings have on their inside a curved edge and a substantially in a radial direction flowing against edge.

Out JP 2007002770 A For example, a vacuum cleaner with a blower is known which comprises a diffuser. On an outer side of the radial impeller, a plurality of blades are arranged in an annular space, which guide the air flow conveyed by the impeller. Below the vanes, a plate is arranged, which has at its outer edge substantially triangular recesses through which the air flow reaches the bottom of the plate, where it is guided by return vanes in the direction of the axis of rotation.

The problem underlying the invention

It is the object of the present invention to specify a generic radial fan, in particular a radial fan for a vacuum cleaner, in which the aerodynamic efficiency is increased and / or the generated sound power level is reduced.

Inventive solution

The reference numbers in all claims have no limiting effect, but are only intended to improve their readability.

The solution of the problem is achieved by a radial fan with the features of claim 1.

An inventive radial fan, which is designed in particular for use in a vacuum cleaner, preferably in a battery or battery-operated hand vacuum cleaner, comprises an impeller which is rotatably mounted about a rotation axis and by a motor, in particular an electric motor driven. The impeller has a plurality of blades arranged to produce a radially outward airflow. The blades are preferably arranged obliquely to a radial direction and curved backward when the impeller rotates in a direction of rotation from the inside to the outside. If the impeller is set in rotation by the motor, an air flow directed at least partially radially outwards is thereby produced, which is discharged at a periphery of the impeller into a space adjoining the impeller to the outside. The fact that the air flow is at least partially directed radially outwards, means here that a flow direction of the generated air flow has an outwardly directed component; Due to the entrainment of the air by the blades of the impeller, the direction of flow of the air flow generally also has a tangential component which may exceed the radial magnitude. Thus, the airflow may leave an angle of less than 30 ° when leaving the impeller with a tangential direction of the impeller. The generated air flow is uniform in particular along the peripheral surface of the impeller. The air conveyed by the impeller is fed to the impeller in the axial direction in the vicinity of the axis of rotation. The supplied air flow can be used in a vacuum cleaner to achieve the suction effect. The blades of the impeller may be arranged on a base disk of the impeller or at least partially free. As used herein, the term "periphery" or "peripheral surface" of the impeller refers to a substantially cylindrical surface that produces the radially outer edges of the blades of the impeller upon rotation of the impeller.

The radial fan further comprises a guide device, which serves for deflecting the air flow generated by the rotating impeller in an axial direction and which is not rotatable. That the air flow has an axial direction means in this case that at least one mean flow direction of the air flow has an axially directed component; In addition, radial and / or tangential components of the flow direction may also be present. The guide device is designed as a plate diffuser, which has a diffuser plate arranged adjacent to the impeller in the axial direction, an annular wall surrounding the latter radially on the outside, and a hood which at least partially surrounds the impeller. The diffuser plate is substantially disc-shaped and preferably arranged in a plane perpendicular to the rotation axis at a small distance from the impeller, wherein the axis of rotation pierces the diffuser plate in a central region. The annular wall may be connected to the hood or formed integrally therewith. The hood and / or the annular wall may be part of a housing of the radial fan. The diameter of the diffuser plate is larger than the diameter of the impeller; the ratio of the outer diameter of the impeller to that of the diffuser plate is in particular 0.8 to 0.9. As a result, a circumferentially continuous annular space is formed between the hood, the impeller and the diffuser plate, in which the generated air flow is conveyed by the impeller. In the annular space creates an air flow having an at least partially radially outward flow direction, which may have a tangential component due to the entrainment of the air through the blades of the impeller.

The diffuser plate lies with its outer edge at least at points on the annular wall or is at least selectively connected thereto. Between the outer edge of the diffuser plate and the inside of the annular wall is formed by recesses of the diffuser plate a plurality of distributed along the outer periphery of the diffuser plate openings which allow air to pass from the annular space in a space formed on the opposite side of the impeller of the diffuser plate. In the latter space guide channels can be arranged, through which the air flow is guided in the course; the guide channels can be formed for example by arranged on the diffuser plate ribs and the generated air flow radially inwardly to the vicinity of the axis of rotation, where the air flow can be deflected in the axial direction and then used to cool the engine. In the area of each opening, the outer edge of the diffuser plate due to the Annular space prevailing flow direction of the air flow at least one streamed by the air flow and at least one overflowed by the air flow edge portion. In a streamlined edge portion, the flow direction, which typically has a radial and a tangential component, is directed against the edge and directed away from the edge in an overflowed edge portion. The outer edge of the diffuser plate may have further edge portions, for example, a tangential edge portion which may abut the annular wall. Preferably, the side facing the impeller of the diffuser plate is substantially flat, so that the flowed and the overflowed edge portion lie in a plane, namely in the plane of the diffuser plate.

According to the invention, the outer edge of the diffuser plate is formed in such a way that the at least one overflowed edge section has a partial section which is designed as a circular arc whose center lies on the axis of rotation. One or more further sections of the overflowed edge section may extend at an angle to a tangential direction.

Characterized in that the at least one overflowed edge portion has a shaped as a circular arc with the axis of rotation as the center section, a particularly large cross section of the air flow flowed through openings and thus a high aerodynamic efficiency can be achieved, with a generated sound power level remains at a low level.

Preferred embodiment of the invention

Advantageous embodiments and developments, which can be used individually or in combination with each other, are the subject of the dependent claims.

Advantageously, it is provided that each opening has only one overflowed edge portion, wherein the inner end point of the flowed edge portion coincides with the inner end point of the overflowed edge portion. Preferably, along the overflowed edge portion, a continuation of the inner wall of the guide channel and from the outer end point of the overflowed edge portion to the inlet opening in the guide channel, an inclined ramp descending into the guide channel is arranged. The end of the inclined ramp, together with the adjoining areas of the inner wall and the outer wall of the guide channel as well as the flowed-on edge portion, define an entry opening into the guide channel. In the region of the inclined ramp or the inlet opening, the flow direction of the air flow entering through the inlet opening also has an axial component. This allows a particularly efficient management of the air flow.

With regard to its extension perpendicular to the axial direction, the inlet opening extends in the direction of the axis of rotation beyond the radius of the impeller; in other words, the inlet opening and the impeller overlap each other when the radial fan is viewed in the direction of the axis of rotation. This can be achieved in that the inner wall of the guide channel at the location of the inlet opening has a smaller distance from the axis of rotation than the outer edge of the impeller. As a result, the largest possible volume flow through the inlet opening is advantageously achievable. Preferably, the ratio between the distance of the rotation axis-side boundary of the inlet opening from the axis of rotation and the radius of the impeller is less than 0.95, particularly preferably less than 0.9. Preferably, the ratio between the distance of the rotational axis side boundary of the inlet opening from the axis of rotation and the radius of the impeller is more than 0.7, more preferably more than 0.8, for example, 0.83. A not too small distance of the rotation axis-side boundary of the inlet opening from the axis of rotation can ensure pressure recovery in the inlet opening downstream region of the radial fan.

According to a preferred embodiment of the invention, the at least one overflowed edge portion is arranged at least in sections obliquely to a radial direction relative to the axis of rotation, in particular at an angle of at least 50 ° to the radial direction. According to this aspect of the invention, it has been recognized that an edge vortex can arise at an overflowed edge, which can also represent a sound source. Furthermore, the edge vortex obstruct the free outflow from the impeller and thus adversely affect the efficiency of the fan. Characterized in that the overflowed edge portion is oriented obliquely to the radial direction, the formation of such eddy vortex is reduced or suppressed, whereby the efficiency can be further increased and the sound power level can be further reduced.

Advantageously, the overflowed edge portion is at least partially arcuate, in particular in an arcuate manner in such a way that the center of curvature of the curvature of the overflowed edge portion is arranged radially inside, but offset from the axis of rotation. The overflowed edge portion may also be formed straight in sections. In both cases, it is advantageous for the overflowed edge portion in each section to be at an angle of at least 50 ° and at most 90 ° forms to a radial direction. If the overflowed edge portion comprises a partial section in the form of a circular arc with the axis of rotation as the center, it is advantageous for one or each further partial section of the overflowed edge section to enclose an angle of at least 50 ° and at most 90 ° to a radial direction. As a result, a particularly lossless and low-noise overflow is possible.

According to a preferred embodiment of the invention, each opening has only one flowed edge portion, wherein each opening is associated with a formed on the opposite side of the impeller of the diffuser plate guide channel, which is formed by an inner wall and an outer wall, and with its outer wall to an outer End point of a flowed edge section connects. The streamlined edge portion thus covers the guide channel. The inner wall and the outer wall may be formed as ribs of the diffuser plate, wherein one rib at a time is the outer wall of a guide channel and the inner wall of an adjacent guide channel. The guide channels can be open on the side facing away from the diffuser plate or at least partially closed by a bottom. The guide channels serve to guide the generated air flow, in particular in an obliquely inward direction, i. with a flow direction with a radially inward and a tangential component. Due to the fact that the guide channel assigned to an opening connects in each case to the flowed edge section, a maximum cross-sectional area of the guide channel and thereby a particularly high efficiency of the blower are made possible.

According to a preferred embodiment of the invention, the outer edge of the diffuser plate is formed so that at least one, preferably each flown edge portion at an angle of at least 50 ° and at most 65 °, preferably at least 50 ° and at most 60 °, more preferably at an angle of about 55 °, to a relative to the axis of rotation radial direction. The at least one flowed-on edge section can form an obtuse angle, in particular with an edge section adjoining the inner end of the flowed-on edge section. By virtue of the fact that at least one, preferably each, flowed-on edge section encloses an angle of at least 50 ° and at most 65 ° to a radial direction, it can be ensured in particular that the flowed edge section is not perpendicular, even not approximately perpendicular, to the flow direction of the air in the annular space in any area stands. As a result, it can be achieved that the air is slowed down to a lesser extent when flowing against the flowed-on edge section and thus a higher air volume flow is made possible. Furthermore, the oscillation amplitude of pressure fluctuations, which arise in the flow of the edge through the pulsating due to the blading of the impeller air flow and contribute significantly to the sound level generated by the fan, can be reduced in this way. In this way, a further increased aerodynamic efficiency and / or a further reduction of the overall sound power level can be made possible.

Preferably, the at least one streamlined edge portion is formed substantially straight. This allows for a particularly simple design high efficiency at a low sound power level.

According to an alternative embodiment, the at least one flowed-on edge portion is curved or partially straight and includes an angle of at least 50 ° and at most 65 ° with a radial direction relative to the rotation axis. Preferably, exactly one flowed-on edge portion is provided, and this is formed concavely curved, wherein a straight connecting line between a radially outer and a radially inner end point of the flowed edge portion forms an angle of about 65 ° with a radial direction. In a particularly advantageous manner, the flowed-on edge portion is concavely curved such that the area of the opening of the diffuser plate bounded by this is equal to the area of such an opening formed by a straight-edged straight edge portion having the same outer end point and a radial direction Angle of 55 ° is limited. As a result, a particularly high efficiency and / or a particularly low sound level can also be achieved.

According to a preferred embodiment of the invention, the plurality of openings are distributed uniformly on the circumference of the diffuser plate and in particular each have the same shape and size. As a result, a simplification of the production as well as a particularly uniform air flow are made possible.

Furthermore, it is preferred that the outer end point of the flowed edge portion of a first opening adjacent to the outer end point of the overflowed edge portion of a second opening or coincides with this. Preferably, this applies to each opening, so that the openings join each other almost completely and occupy virtually the entire outer circumference of the diffuser plate; a contact with the annular wall, which limits the opening to the outside, thus takes place only selectively, namely at the outer end points of the streamed or overflowed Edge portions. This makes it possible to form the openings with a maximum area, so that a particularly high air flow rate or a particularly low flow resistance is made possible.

According to a preferred embodiment of the invention, the openings are arranged outside the surface of the diffuser plate swept by the blades of the impeller. This means that the inner end point of the flowed as well as the overflowed edge portion are at a greater or equal distance from the axis of rotation than corresponds to the radius of rotation of the outer ends of the blades of the impeller. If the overflowed edge portion has a section formed as a circular arc with a center lying on the axis of rotation part section, it is particularly advantageous that the circular arc has a radius which corresponds approximately to the outer radius of the impeller. This not only allows maximum use of the passage area of the openings, but also a more efficient guidance of the air flow.

In a further advantageous manner, the diffuser plate is integrally formed with the annular wall or the diffuser plate and the annular wall are connected by a suitable joining method, such as ultrasonic welding or gluing. The diffuser plate together with the annular wall thus represents a deflecting body, which deflects the air flow from the annular space for further use in the axial direction and possibly radially inwardly. The deflecting body, such as the impeller and the hood, are preferably made of plastic. As a result, a particularly simple production and / or assembly is possible.

Brief description of the drawings

Further advantageous embodiments will be described in more detail below with reference to two embodiments illustrated in the drawings, to which the invention is not limited.

They show schematically:

1 a radial fan according to the two embodiments of the invention described below in an axial longitudinal section;

2 the impeller of the radial fan according to 1 and a tracking device according to an embodiment of the invention in a perspective view;

3 again the Nachleiteinrichtung according to 2 in a perspective view;

4 a guide device according to the embodiment of the invention with the impeller in a schematic plan view;
and finally

5 the Nachleiteinrichtungen according to 2 to 4 with the impeller in a schematic, partially sectioned side view.

Detailed description based on an embodiment

In the following description of a preferred embodiment of the present invention, like reference characters designate like or similar components. For clarity, not all figures are shown in all figures.

In 1 is in an axial longitudinal section, for example, suitable for a battery-powered hand-held vacuum cleaner radial fan 1 shown that an impeller 2 , a tracking device 3 and an electric motor 4 includes. The impeller 2 consists of a disc-shaped base plate 5 and a likewise disk-shaped, in the central area slightly high arched cover plate 6 between which are a plurality of blades 7 is arranged. The impeller 2 is rotatably mounted and is powered by the electric motor 4 over a wave 8th driven. The axis of rotation of the shaft 8th or the impeller 2 is in 1 with the reference number 9 characterized. The engine includes, as in 1 symbolically shown is a stator 10 and one with the wave 8th connected rotor 11 and has a plurality of windings 12 on, which are traversed by the drive current of the electric motor.

The tracking device 3 is designed as a plate diffuser and includes a circular diffuser plate 48 having a substantially planar upper side and parallel to the base plate 5 of the impeller 2 is arranged at a small distance below this. The outer diameter of the diffuser plate 48 is larger than the outer diameter of the impeller 2 ; the ratio of the outer diameter of the impeller 2 to the diffuser plate 48 is about 0.88. At its outer edge is the diffuser plate 48 with a short cylindrical annular wall 14 connected. Furthermore, the diffuser plate 48 on its underside a plurality of ribs 15 on, the downwardly open guide channels 16 form, through which one through in 1 not shown air passage openings through the diffuser plate 48 passed through air flow is guided radially inwardly. In the edge area of the diffuser plate 48 are below the air passage openings oblique ramps 43 arranged, the passing through the openings of the air into the guide channels 16 into conduct. In the area near the axis, the diffuser plate 48 a slope 18 for further deflection of the air flow in a radial direction. The radial fan also has a housing 19 on, that from a housing lower part 20 , a hood 21 and a suction flange 22 and optionally further, in 1 not shown components. The diffuser plate 48 with the ring wall 14 is in the case 19 fixedly arranged. The hood 21 encloses the impeller 2 and partly the diffuser plate 48 and the ring wall 14 , wherein between the periphery, ie the outer peripheral surface of the impeller 2 , the top of the diffuser plate 48 and the inside of the hood 21 an annulus 23 is formed. The annulus 23 is along the circumference of the impeller 2 formed continuously and contains no flow-conducting elements.

Will the impeller 2 from the electric motor 4 over the wave 8th in one by the arrow 24 indicated, predetermined direction of rotation set in rotation, so generates the impeller 2 with the help of the blades 7 an at least partially radially outwardly directed airflow as in 1 indicated by the arrows. To replace the air delivered to the outside by the impeller, air is sent along the axis of rotation 9 through the intake flange 22 sucked, which may be in a vacuum cleaner, for example, with a suction hose in connection. The extracted air reaches the annulus first 23 where they are due to the entrainment by the blades 7 also a tangential to the axis of rotation 9 directed movement. By the in 1 not shown openings in the diffuser plate 48 the generated airflow passes over the ramp 43 into the space below the diffuser plate 48 and in the guide channels 16 through which it is guided radially inwards while retaining a tangential component. In the area near the axis of the diffuser plate 48 the airflow is through the slope 18 further deflected in the axial direction and reaches the electric motor 4 where he used to cool the windings 12 can be used. Through outlet openings 25 Finally, the air flow reaches the outside of the fan 1 , The radial and axial components of the flow direction of the generated air flow are in the in 1 to recognize shown sectional view with reference to the arrows.

In 2 are in perspective view an impeller 2 and a tracking device 3 according to an embodiment of the invention in a perspective view, wherein for purposes of illustration, the hood 21 has been omitted. As in 2 can be seen, points the impeller 2 a base plate 5 and a cover plate 6 on, between which several, for example 13 , vertical, arcuately curved blades 7 are arranged. The shovels 7 are equidistantly spaced from each other and overlap each other, each blade, as viewed from the axis of rotation, covering an angle of approximately 50 °. The cover plate 6 has a central recess 26 on, which is an axial flow of air into the central area of the impeller 2 allows. In the base plate 5 is a hole 27 introduced into the drive of the impeller 2 the one with the rotor 11 of the electric motor 4 connected wave 8th used and with the impeller 2 can be connected (s. 1 ). Will the impeller 2 moved in the predetermined direction of rotation, so is by the inclined, backward curved blades 7 generates an obliquely outwardly directed air flow. Below the base plate 5 and parallel to this is the diffuser plate 48 arranged, whose outer edge with the ring wall 14 a plurality of openings 50 Are defined. Through the openings 50 the air flow enters the impeller from the outside 2 subsequent annulus, which is upwards and outwards through the in 2 not shown hood 21 is limited (s. 1 ), in the space below the diffuser plate 48 one. There the airflow, how to 1 explained, guided radially inward and finally deflected again in the axial direction. As in 2 is shown, the opening 50 the diffuser plate 48 in the flow direction of the air flow generated in the annular space by a flowing in the axial direction of the flowed edge 34 limited.

In 3 are the diffuser plate 13 and the ring wall 14 the tracking device 3 a trained according to the embodiment of the invention radial fan again shown in perspective; the impeller 2 and the hood 21 are not shown for reasons of clarity. To carry out the wave 8th to drive the impeller 2 has the diffuser plate 48 a central hole 36 on. Between the ring wall 14 and the outer edge of the diffuser plate 48 are in the example shown eight openings 50 formed along the circumference of the diffuser plate 48 evenly distributed. Each opening is outwardly through the inner wall of the short-cylindrical annular wall 14 limited. Inside, every opening becomes 50 by a streamlined edge portion 34 and an overflowed edge portion 49 the outer edge of the diffuser plate 48 limited. The streamed edge section 34 runs approximately in the radial direction. The overflowed edge section 49 has a to the flowed edge portion 34 subsequent first section 46 which has the shape of a circular arc whose center is in the center of the diffuser plate 48 ie at the center of the central hole 36 lies. The radius of the circular arc corresponds to the radius of the impeller 2 , so that the first section approximately in extension of the peripheral surface of the impeller 2 to come to rest. A second section 47 of the overflowed edge section 49 is arcuate and forms with a radial direction an angle θ between 50 ° and 90 °, in the illustrated example of about 80 °, ie with a tangential direction an angle of about 10 °. Overall, the opening has 28 approximately the shape of a rectangular trapezoid.

In 4 is the diffuser plate 48 along with the impeller 2 schematically shown in plan view. In the middle of the circular base plate 5 is to drive the impeller 2 the wave 8th attached. On the base plate 5 stand the oblique, backward curved blades 7 , The base plate 5 covers the central area of the diffuser plate 48 , The ratio of the outside diameter of the base plate 5 or the impeller 2 to the outer diameter of the diffuser plate 48 is about 0.88. Through the solid arrows 37 is in 5 the flow direction of the impeller 2 conveyed air relative to the impeller 2 indicated. The cover plate 6 of the impeller 2 (S. 1 and 2 ) is in 4 not shown.

The diffuser plate 48 has peripheral recesses, which together with the annular wall 14 the majority of openings 50 form; for clarity, one of the openings 50 in 4 characterized by hatching. On the outside are the openings 50 through the ring wall 14 limited. Inside are the openings 50 through the outer edge of the diffuser plate 48 limited, in the area of the openings a flowed edge portion 34 and an overflowed edge portion 49 having. The streamed edge section 34 is straight and does not extend in the radial direction in the embodiment but forms an angle γ = 55 ° therewith. The overflowed edge section 49 is with two sections 46 . 47 educated. A first section 46 of the overflowed edge section 49 closes at the flowed edge section 34 at, wherein the first section 46 has the shape of a circular arc whose center is in the center of the diffuser plate 48 , ie on the axis of rotation of the impeller 2 or in the center of the central hole 36 lies (s. 3 ). The radius of the circular arc corresponds to the radius of the impeller 2 so that the first subsection 46 approximately in extension of the peripheral surface of the impeller 2 to come to rest. A second section 47 of the overflowed edge section 49 is formed arcuate convexly curved and forms with a radial direction an angle θ between 50 ° and 90 °, in the illustrated example of about 80 °, ie with a tangential direction an angle of about 10 °. For the sake of simplicity, in 4 only two openings 50 with an overflowed edge section formed in this way 49 shown; the remaining openings are also formed in 4 but only symbolically indicated. The openings 50 be through the impeller 2 not covered, ie the distance between the openings 50 from the axis of rotation is at least as large as the radius of the impeller 2 , Overall, between the ring wall 14 and the outer edge of the diffuser plate 48 eight openings 50 educated. For the sake of simplicity, in 5 only two openings 50 with an overflowed edge section formed in this way 49 shown; the remaining openings are also formed in 5 but only symbolically indicated.

The solid arrows 38 show the flow direction of the impeller 2 conveyed air flow in the annulus outside the impeller 2 and above the diffuser plate 48 relative to this. When exiting the impeller 2 The flow direction of the air is at an angle of less than 30 ° to a tangential direction. Below the diffuser plate 48 the air flow is through in 5 Guided channels not shown guided. To improve the entry of the air flow into the guide channels is in the area of the opening 50 one ramp each 43 arranged in the area of the outer endpoint 40 the overflowed edge 49 at the level of the top of the diffuser plate 48 begins and to the streamed edge 34 falls off, leaving between the ramp 43 and the streamed edge 34 an inlet opening for the entry of air into the guide channel 16 is formed. The inner endpoint 39 the streamed edge 34 and the overflowed edge 49 fall together. Likewise fall the outer endpoint 40 the flowed edge of an adjacent opening 50 and the overflowed edge 49 together. Incidentally, the diffuser plate 48 like that too 2 and 3 described diffuser plate 48 formed, wherein the reference numerals have the same meaning, as well as a radial fan according to the invention in the described embodiment as before to the 1 to 3 explained. The flow direction of one below the diffuser plate 48 in a guide channel 16 guided air flow is indicated by the dashed arrows 41 indicated.

The passage of the air flow through the diffuser plate 48 is in the in 5 shown, partially sectioned side view shown. As in 5 can be seen, the passes through the arrows 42 indicated air flow from the annulus 23 through the in 5 not shown opening 50 into the space below the diffuser plate 48 , The airflow is through an inclined ramp 43 guided at the outer endpoint 40 the overflowed edge 49 begins (s. 4 ). On the side, the air flow in this area is on the one hand through the annular wall 14 and on the other hand by one along the overflowed edge 49 extending or slightly inwardly offset, vertical outer side wall 44 the rib 15 guided. The air flow then passes through the between the diffuser plate 48 in the area of the streamed edge section 34 and the end of the ramp 43 formed, slightly obliquely to an axial direction standing inlet opening 45 into the space below the diffuser plate 48 where a guide channel 16 to further guide the air (in 5 Not shown). to Clarification are two inlets in 5 hatched shown. In a radial fan formed according to the embodiment of the invention, the passage of the air flow through the diffuser plate takes place 48 in the same way as in 5 for the embodiment shown.

As in 5 also recognizable, has the outer side wall 44 the rib 15 a smaller distance from the axis of rotation than the outer edge of the impeller 2 , As a result, the inlet opening extends 45 in the direction of the axis of rotation 9 over the radius of the wheel 2 out so that entrance opening 45 and impeller 2 cover. The ratio between the distance of the rotation axis side boundary of the inlet opening 45 from the axis of rotation 9 and the radius of the impeller 2 is 0.83.

The features disclosed in the foregoing description, the claims and the drawings may be of importance both individually and in any combination for the realization of the invention in its various forms.

LIST OF REFERENCE NUMBERS

1

 centrifugal blower

2

 Wheel

3

 further conducting

4

 electric motor

5

 baseplate

6

 cover plate

7

 shovel

8th

 wave

9

 axis of rotation

10

 stator

11

 rotor

12

 winding

14

 ring wall

15

 rib

16

 guide channel

18

 slope

19

 casing

20

 Housing bottom

21

 Hood

22

 suction flange

23

 annulus

24

 arrow

25

 outlet

26

 recess

27

 drilling

34

 Onflowed edge section

36

 drilling

37

 arrow

38

 arrow

39

 endpoint

40

 endpoint

41

 arrow

42

 arrow

43

 ramp

44

 Side wall

45

 inlet opening

46

 part Of

47

 part Of

48

 diffuser plate

49

 Onflowed edge section

50

 opening

γ

 Angle of the streamed edge

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• EP 0773620 B1 [0004]
• JP 11-206630 A [0005]
• JP 2007002770 A [0006]

Claims (12)

Radial blower, in particular for a vacuum cleaner, comprising a rotary axis ( 9 ) rotatable, driven by a motor impeller ( 2 ), which has a plurality of blades ( 7 ) for generating an at least partially radially outward air flow, and a fixed Nachleiteinrichtung ( 3 ), which is perpendicular to the axis of rotation ( 9 ) axially adjacent to the impeller ( 2 ) arranged diffuser plate ( 48 ), this radially outwardly surrounding annular wall ( 14 ) and one the impeller ( 2 ) at least partially enclosing hood ( 21 ), wherein between the hood ( 21 ), the impeller ( 2 ) and the diffuser plate ( 48 ) the impeller ( 2 ) radially outer surrounding, continuous annular space ( 23 ) is formed, wherein between an outer edge of the diffuser plate ( 48 ) and the ring wall ( 14 ) a plurality of openings ( 50 ) is formed, which is an air passage from the annular space ( 23 ) to the impeller ( 2 ) opposite side of the diffuser plate ( 48 ) and wherein the outer edge of the diffuser plate ( 48 ) in the area of each opening ( 50 ) at least one streamlined edge portion ( 34 ) and at least one overflowed edge portion ( 49 ), characterized in that the at least one overflowed edge portion ( 49 ) a subsection ( 46 ), which is in the form of a circular arc whose center is on the axis of rotation ( 9 ), is formed. Radial fan according to claim 1, characterized in that each opening ( 50 ) exactly one overflowed edge portion ( 49 ), the inner endpoint ( 39 ) of the streamed edge portion ( 34 ) with the inner endpoint ( 39 ) of the overflowed edge section ( 49 ) coincides and along the overflowed edge portion ( 49 ) a continuation of the inner wall of the guide channel ( 16 ) and from the outer end point of the overflowed edge section ( 49 ) to the entrance opening ( 45 ) in the guide channel ( 16 ) an inclined ramp ( 43 ) is arranged. Radial fan according to claim 1 or 2, characterized in that the at least one overflowed edge portion ( 49 ) at least in one subsection ( 47 ) extends obliquely to a radial direction, in particular with a radial direction forms an angle θ of at least 50 °. Radial fan according to one of the preceding claims, characterized in that the at least one overflowed edge portion ( 49 ) at least in one subsection ( 47 ) is arcuate. Radial fan according to one of the preceding claims, characterized in that each opening ( 50 ) exactly one streamed edge section ( 34 ) and that each opening ( 50 ) on the impeller ( 2 ) opposite side of the diffuser plate ( 48 ) arranged guide channel ( 16 ), wherein an inner wall of the guide channel ( 16 ) at an inner endpoint ( 39 ) and an outer wall of the guide channel ( 16 ) at an outer end point of the streamed edge portion ( 34 ). Radial fan according to one of the preceding claims, characterized in that the at least one streamed edge portion ( 34 ) with an radial direction at an angle γ of at least 50 ° and at most 65 °, preferably at least 50 ° and at most 60 °, more preferably an angle γ of about 55 °. Radial fan according to one of the preceding claims, characterized in that the at least one streamed edge portion ( 34 ) is substantially straight. Radial fan according to one of claims 1 to 7, characterized in that the at least one streamed edge portion ( 34 ) is curved or sectionally straight, wherein the flowed edge portion ( 34 ) includes at each point an angle γ of more than 50 ° at most 65 ° with a radial direction, the opening ( 50 ) has an area of the same size as an opening with a streamlined edge section ( 34 ) including an angle γ = 55 ° with a radial direction. Radial fan according to one of the preceding claims, characterized in that the plurality of openings ( 50 ) evenly along the circumference of the diffuser plate ( 48 ) are distributed. Radial fan according to one of the preceding claims, characterized in that the outer end point of a streamed edge portion ( 34 ) an opening ( 50 ) the outer end point of an overflowed edge portion ( 49 ) of an adjacent opening ( 50 ) is adjacent or coincident with it. Radial fan according to one of the preceding claims, characterized in that the openings ( 50 ) outside of the blades ( 7 ) of the impeller ( 2 ) swept surface of the diffuser plate ( 48 ) are arranged. Radial fan according to one of the preceding claims, characterized in that the diffuser plate ( 48 ) with the annular wall ( 14 ) is integrally formed or joined together with it, thereby forming a deflecting body.

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