EP0450272A2 - Radial fan with an internal spiral - Google Patents

Abstract

The invention relates to a radial fan (2), especially for delivering gaseous media. It comprises a housing (4) with a peripheral wall (6), a front (8) and a rear (10) end wall, an inlet opening (12) in the front end wall (8) and an outlet opening (14) in the peripheral wall (6). Inside the housing (4) a radial impeller wheel (20) is rotatably arranged about an axis of rotation (16), which wheel has a rear cover plate (24) with radial rotor blades (26) connected to a drive shaft (22) and a front cover plate (28) with a central admission opening (34) connected to the rotor blades on their side axially opposite the rear cover plate (24). An internal spiral chamber (36), open in the direction of the impeller wheel and passing into the outlet opening (14), is formed inside the housing (4) next to the impeller wheel (26). The front cover plate (28) of the impeller wheel (20) merges in its outer peripheral area via a dished and, seen in axial cross section, arched transitional area (52) into an outer annular web (54) extending essentially axially in the direction of the internal spiral chamber (36).

Description

The present invention relates to a radial fan for conveying in particular gaseous media, consisting of a housing with a peripheral wall, a front and a rear end wall, an inlet opening in the front end wall and a blow-out opening in the region of the peripheral wall, as well as one within the housing around a Rotary axis rotatably arranged radial impeller, which has a rear cover disk connected to a drive shaft with essentially radial radial vanes extending in the axial direction from the rear cover disk in the direction of the front end wall, and one axially with the rotor blades on the rear cover disk Has opposite side connected, approximately perpendicular to the axis of rotation, front cover plate with an inflow opening arranged in the region of the housing inlet opening, wherein within the housing on the in the axial direction of the front cover plate turned side next to the impeller an inner spiral chamber is formed in the direction of the impeller, widening in the direction of impeller rotation and merging into the blow-out opening.

Such a radial fan is described in EP-A1-0 316 470. Because of the inner spiral chamber formed inside the housing and arranged in the axial direction next to the impeller, the outer peripheral wall of the housing can be cylindrical and of small dimensions. In the known radial fan, the rotor blades of the impeller end with their radially outer ends in the immediate vicinity of the inner surface of the housing peripheral wall, the rear cover disk facing the inner spiral chamber having an annular opening opening into the inner spiral chamber in the axial direction. Because of this configuration, the known radial blower has proven itself particularly well with regard to low noise. However, for some applications, such as in the air and / or gas supply or in the exhaust gas discharge of gas-fired boilers, there is a requirement for particularly high pressure with the steepest possible pressure / volume flow characteristic so that the volume flow of the medium to be conveyed (e.g. fresh air, exhaust gases or air / gas mixture) changes very little.

Accordingly, the present invention has for its object to improve the generic radial fan so that a high pressure and a steep pressure / volume flow characteristic can be achieved.

According to the invention, this is achieved in that the front cover disk of the impeller merges in its outer circumferential region via a shell-like curved transition region, seen in the axial section, into an outer annular web which extends approximately axially in the direction of the inner spiral chamber. By means of this configuration according to the invention, an improved and lower-loss deflection of the flow within the impeller from the radial direction into the axial direction into the Inner spiral chamber transcending direction reached. Due to this improved flow control, a very steep characteristic curve can be achieved.

It is also particularly advantageous here if the rear cover disk of the impeller facing the inner spiral chamber has such a small outer diameter that it is arranged without overlap for the axial projection of the opening of the inner spiral chamber. As a result, the medium to be delivered can advantageously flow from the impeller in the axial direction over the entire opening width of the inner spiral chamber. The flow is practically loss-free in this area as well. For this purpose, it is also expedient if the impeller delimited in the radial direction by the outer annular web of the front cover disk approximately completely covers the axial projection of the inner spiral chamber. This forms an annular opening cross section between the outer circumference of the rear cover disk and the outer annular web of the front cover disk, which cross section according to the invention is larger than or at least equal to the opening cross section of the inner spiral chamber. The two opening cross sections lie opposite one another in the axial direction, as a result of which a maximum cross section is available for the flow of the medium.

In an advantageous development of the invention, the front cover disk also merges in the area of its inflow opening via an arc-shaped area, seen in axial section, into an inner annular web which extends approximately radially in the direction of the housing inlet opening and surrounds the inflow opening. This also results in a low-loss deflection of the medium from the axial into the radial direction in this area.

Due to the configuration according to the invention, a very steep pressure / volume flow characteristic can be achieved, so that in the event of a pressure change, for example a change in a chimney pressure, the volume flow of the medium required is only subjected to minor changes. This advantageously makes it unnecessary to readjust the speed of a drive motor, ie to adapt the volume flow to the new pressure conditions.

The radial fan according to the invention is therefore particularly suitable for use as a so-called "gas fan" for gas-fired boiler systems. With the radial fan according to the invention, the efficiency of such boiler systems can be increased. The relatively high flow resistances within the boiler systems are advantageously overcome due to the high pressure reached.

Further advantageous embodiments of the invention are contained in the subclaims and the following description.

Fig. 1

eine Ansicht eines erfindungsgemäßen Radialgebläses in Richtung auf die Ausblasöffnung, d.h. in Pfeilrichtung I gemäß Fig. 2,

Fig. 2

eine Ansicht auf die Antriebsseite in Pfeilrichtung II gemäß Fig. 1,

Fig. 3

einen Axialschnitt durch das erfindungsgemäße Radialgebläse längs der Linie III-III in Fig. 2,

Fig. 4

einen Querschnitt durch das Laufrad des erfindungsgemäßen Radialgebläses längs der Linie IV-IV in Fig. 3 ohne Darstellung des Gehäuses und

Fig. 5

ein Diagramm mit Darstellung der Druck/Volumenstrom -Kennlinie.

Based on an embodiment shown in the drawing, the invention will be explained in more detail below. Show:

Fig. 1

3 shows a view of a radial fan according to the invention in the direction of the blow-out opening, ie in the direction of arrow I in accordance with FIG. 2,

Fig. 2

2 shows a view of the drive side in the direction of arrow II according to FIG. 1,

Fig. 3

3 shows an axial section through the radial fan according to the invention along the line III-III in FIG. 2,

Fig. 4

a cross section through the impeller of the invention Radial blower along the line IV-IV in Fig. 3 without showing the housing and

Fig. 5

a diagram showing the pressure / volume flow characteristic.

In the different figures of the drawing, the same parts are always designated with the same reference numbers.

A radial fan 2 according to the invention consists of a housing 4 with an essentially cylindrical or hollow cylindrical peripheral wall 6, a front end wall 8 and a rear end wall 10. The housing 4 furthermore has an axial inlet opening 12 in the front end wall 8 and one in to the peripheral wall 6 open discharge opening 14 approximately tangential direction.

3 and 4, a radial impeller 20 is arranged within the housing 4 concentrically to the peripheral wall 6 and rotatable about an axis of rotation 16, which has a circular, e.g. Has a rear cover disk 24 connected to a drive shaft 22 via a hub 21, with radial rotor blades 26 arranged essentially radially and extending forward in the axial direction from the rear cover disk 24 and distributed over their circumference. Furthermore, the impeller 20 also has a front cover disk 28 connected to the rotor blades 26 on their side axially opposite the rear cover disk 24.

In the exemplary embodiment shown, the rotor blades 26 are curved forward, which advantageously ensures a high delivery rate with low running noise. However, the invention is in no way limited to this, but the impeller 20 can also have backward curved or straight running blades 26. The blades 26 can furthermore have a blade depth measured in the axial direction, which decreases in the radial direction from the inside to the outside or is essentially constant.

The drive shaft 22 extends through the rear end wall 10 of the housing 4 and is connected to a drive motor 30 fastened to this end wall 10, which is preferably a collectorless DC motor. However, other types of engine are also possible.

The blades 26 lie with their inner ends 31 in the radial direction on the circumference of an axial inlet 32 which is circular in cross section and which is substantially aligned with the circular inlet opening 12 of the front end wall 8 in the axial direction (axis 16). The front cover plate 28 has a likewise circular inflow opening 34, which in the exemplary embodiment shown has a somewhat larger diameter than the inlet opening 12, so that the blades 26 extend with their inner ends 31 inwards beyond the front cover plate 28 (see FIG. 3 and 4). The center points of the openings 12 and 34 and the center axis of the inlet 32 lie on the axis of rotation 16. The front cover disk 28 is consequently - due to the inflow opening 34 - in the form of an annular disk.

Inside the housing 4 is on the side of the impeller 20 which faces the motor 30 in the axial direction by means of a housing wall 10a which extends from the rear end wall 10 and extends axially away from the impeller 20 and a housing wall which adjoins this and extends radially outwards 10b (see in particular FIGS. 2 and 3) an inner spiral chamber 36 is formed, which is in the direction of rotation of the impeller (Arrow 38 in FIGS. 2 and 4) expanded in cross section and merges into the blow-out opening 14. For this purpose, the axial housing wall 10a according to FIG. 2 runs approximately in a spiral. This configuration results in a recess in the area of the rear end wall 10 which is enclosed by the inner spiral chamber 36 (walls 10a and 10b) and in which the motor 30 fastened to the end wall 10 is seated. This leads to a short axial length of the radial fan 2 according to the invention.

The housing 4 is formed in two parts, the peripheral wall 6 with the front end wall 8 forming a housing front part 42 and the rear end wall 10 with the housing walls 10a and 10b forming a housing cover 44. The housing cover 44 is detachably connected to the housing front part 42; Further details will be explained in the following.

The blow-out opening 14 of the housing 4 is also offset from the impeller 20 in the axial direction due to the axial offset of the inner spiral chamber 36 with respect to the impeller 20. The blow-out opening 14 is in the housing peripheral wall 6 i.w. Tangentially arranged or integrally formed blow-out nozzle 46, which preferably has a rectangular flow cross section. The blow-out connector 46 has a front end wall 48 which is perpendicular to the blow-out direction (arrow 47 in FIG. 2) and which extends like a flange beyond the blow-out cross-section or blow-out opening 14 and has fastening holes 49.

As can be seen in particular from FIG. 3, according to the invention, the front cover disk 28 of the impeller 20 goes in its outer circumferential area via a shell-like curved transition area 52, as seen in the axial section shown, into an approximately axial direction in the direction of FIG Inner spiral chamber 36 extending outer ring web 54 over. In the exemplary embodiment shown, this outer ring web 54 already ends in front of the radial edges of the rotor blades 26 facing the inner spiral chamber 36. Alternatively, however, it is also conceivable that the ring web 43 extends axially completely over the outer end edges of the radial rotor blades 26. It is only essential that the end of the ring web 54 points approximately in the axial direction, ie in the direction of the inner spiral chamber 36, so that the medium is deflected well from the radial into the axial direction.

As can also be seen in FIG. 3, the rear cover plate 24 of the impeller 20 has such a small outside diameter that it is completely free of overlap with the opening cross section of the inner spiral chamber 36 that faces the impeller 20 axially. This means that the rear cover disk 24 does not protrude with its outer circumference into the area of the inner spiral chamber 36, so that the medium to be conveyed advantageously has an optimal, i.e. practically loss-free deflection can flow into the inner spiral chamber 36. For this purpose, it is also expedient if the impeller 20 delimited in the radial direction by the outer ring web 54 of the front cover disk 28 has an outer diameter such that it essentially completely covers the largest diameter of the inner spiral chamber 36.

According to FIG. 3, the front cover disk 28 has an inner ring web 56 which surrounds the inflow opening 34 and extends approximately axially in the direction of the housing inlet opening 12, the cover disk 28 advantageously again in this inner ring web 56 via an arcuate region 58, seen in axial section transforms. As a result, there is an almost loss-free deflection of the medium in this area too guaranteed from the axial to the radial direction. In this context, it is furthermore expedient if the hub 21 of the rear cover disk 24 tapers from the cover disk 24 in the axial direction, in particular in cross-section approximately in an arc shape, specifically in a concave manner. This configuration, in conjunction with the arcuate region 58 and the inner annular web 56 of the front cover plate 28, contributes to a particularly good flow guidance for the medium to be conveyed.

According to the invention, the impeller 20, including the front cover disk 28 and the rear cover disk 24 with the hub 21, is made in one piece from plastic. For this purpose, it is expedient if the outer diameter of the rear cover disk 24 is at least slightly smaller than the inner diameter of the inflow opening 34 or of the inner annular web 56 of the front cover disk 28. In this way, a simple demolding of the plastic molded part is possible, in that the molds only need to be pulled apart axially.

1 and 3, the front end wall 8 of the housing 4 has an intake port 60 which surrounds the inlet opening 12 and extends axially away from the impeller 20. As can be seen in particular in FIG. 3, the inner annular web 56 of the front cover disk 28 ends only a short distance in front of the intake manifold 60. The intake manifold 60 is shaped on the inside in such a way that there is a continuous transition between the inner annular web 56 and the intake manifold 60 , ie between the inlet opening 12 and the inflow opening 34 results. This also contributes to a low flow resistance and thus to the desired, steep characteristic curve.

The housing 4, ie the housing front part 42, is expediently located in the transition region between the front end wall 8 and the circumferential wall 6 are adapted at a short distance approximately to the shell-like course of the front cover plate 28.

As already briefly mentioned above, the housing cover 44 is detachably, but preferably also connected to the front housing part 42 in a gas-tight manner. 3, the housing cover 44 has for this purpose a circumferential, axial groove 62, into which the housing peripheral wall 6 of the housing front part 42 engages with its end edge 66 with the interposition of a seal 64. A seal ring or a sealing cord made of an elastic material is suitable as the seal 64, for example. Because of this configuration, the radial blower 2 according to the invention is particularly suitable for so-called “closed systems”, the radial blower sucking in air via a suction pipe that is tightly connected to the suction nozzle 60. A gaseous fuel is then mixed in or in front of the radial fan. This gas / air mixture reaches a burner chamber via a line connection gas-tightly connected to the outlet port 46 and is burned here. The exhaust gases - depending on the delivery rate of the radial fan - are pressed through a heat exchanger and discharged via an exhaust pipe.

1 to 3, the housing cover 44 is connected to the housing front part 42 according to the invention via at least two, but in the exemplary embodiment shown, via three snap-fit connections 70, which are evenly distributed over the circumference of the housing 4. As can be seen in particular in FIGS. 1 and 3, each interlocking connection 70 has a spring-elastic locking arm 72 which extends from the housing cover 44 axially over the peripheral wall 6 of the housing 4 or the housing front part 42 and which has a locking edge 74 with a locking edge 74 radial engagement 76 of the circumferential wall 6 engages behind in a form-locking manner.

Here, the locking edge 74 is formed in the illustrated embodiment by an opening edge of a particularly rectangular locking opening 78 of the locking arm 72. The radial lugs 76 of the circumferential wall 6 each have a ramp inclined surface 80 on their side facing the housing cover 44 (FIG. 3), so that when the housing cover 44 is placed on the housing front part 52, the latching arms 72 are resiliently bent outwards via the ramp inclined surfaces 80 until they engage (snap in) the radial lugs 76 with their locking edges 74.

In the exemplary embodiment shown in FIG. 3, the hub 21 of the rear cover disk 24 is connected in a rotationally fixed manner to the drive shaft 22 via a radially arranged grub screw 82. As an alternative to this, the hub 21 can also be connected in a rotationally fixed manner to the drive shaft 22, for example via a latching connection.

For the present invention, it is particularly advantageous if the motor 30 is designed as a brushless DC motor. On the one hand, this has the advantage that speeds> 3000 rpm are readily possible, and on the other hand, due to the motor characteristic curve, a possible change in the load on the motor also results in only a slight change in speed. So this also has a positive influence on the desired steep characteristic of the radial fan.

Like the impeller 20, the housing 4 can consist of plastic. For the preferred application of the radial fan 2 according to the invention, however, it is particularly advantageous if the housing 4 is made of metal. The housing front part 42 is preferably made of die-cast aluminum. The housing cover 44 is expediently made of a deep-drawn sheet, preferably a fire-aluminum sheet (FAL sheet), educated. Because of these materials, the radial fan 2 according to the invention is particularly well suited for conveying fuel gas / air mixtures, since so-called deflagrations can occur with such media.

5 shows an example of a pressure / volume flow characteristic curve diagram, in which the steep characteristic curve of the radial fan according to the invention is designated by A, while the letter B denotes a flatter characteristic curve of a conventional fan, shown in dash-dot lines. From this diagram it can be seen very clearly that with a certain pressure change Δp in the radial fan according to the invention there is an extraordinarily small change ΔV in the volume flow (m³ / h). In contrast, with the same pressure change Δp in a conventional blower (characteristic curve B), a much larger change in volume flow ΔV 'occurs.

The invention is not limited to the exemplary embodiment shown and described, but also encompasses all embodiments having the same effect in the sense of the invention.

Claims (22)

Radial blower for conveying in particular gaseous media, consisting of a housing with a peripheral wall, a front and a rear end wall, an inlet opening in the front end wall and a blow-out opening in the region of the peripheral wall, as well as a radial inside the housing rotatable about an axis of rotation Impeller, which has a rear cover disk connected to a drive shaft with essentially radially arranged radial rotor blades extending in the axial direction from the rear cover disk in the direction of the front end wall, and an approximately connected to the rotor blades on the side axially opposite the rear cover disk has a front cover disk running perpendicular to the axis of rotation with an inflow opening arranged in the area of the housing inlet opening, an inside of the housing being on the side facing away from the impeller in the axial direction of the front cover disk In the direction of the impeller, an inner spiral chamber is formed which widens in the direction of rotation of the impeller and merges into the outlet opening.
characterized in that the front cover disk (28) of the impeller (20) merges in its outer circumferential area via a shell-like curved transition area (52), seen in the axial section, into an outer ring web (54) which extends approximately axially in the direction of the inner spiral chamber (36). Radial fan according to claim 1
characterized in that the rear cover plate (24) of the impeller (20) has an outer diameter such that it is arranged without overlap for the axial projection of the inner spiral chamber (36). Radial fan according to claim 1 or 2,
characterized in that the impeller (20) delimited in the radial direction by the outer ring web (54) of the front cover disk (28) approximately covers the axial projection of the inner spiral chamber (36). Radial fan according to one or more of claims 1 to 3,
characterized in that the front cover disk (28) in the region of its inflow opening (34) extends over an arcuate region (58), seen in axial section, into a region that extends approximately axially in the direction of the housing inlet opening (12) and encloses the inflow opening (34), inner ring web (56) merges. Radial fan according to one or more of claims 1 to 4,
characterized in that the Outer diameter of the rear cover plate (24) is smaller than the inner diameter of the inflow opening (34) of the front cover plate (28). Radial fan according to one or more of claims 1 to 5,
characterized in that the blades (26) extend with their inner ends (31) inward beyond the front cover plate (28). Radial fan according to one or more of claims 1 to 6,
characterized in that the front end wall (8) of the housing (4) has a suction nozzle (60) which surrounds the inlet opening (12) and extends axially away from the impeller (20). Radial fan according to claim 7,
characterized in that the intake port (60) is formed on the inside in such a manner and is arranged at a short distance from the inner ring web (56) of the front cover plate (28) that there is a continuous transition between the housing inlet opening (12) and the impeller inlet opening (34) results. Radial fan according to one or more of claims 1 to 8,
characterized in that the housing (4) in the transition region between the front housing end wall (8) and the peripheral wall (6) is adapted at a short distance approximately to the shell-like shape of the front cover plate (28). Radial fan according to one or more of claims 1 to 9,
characterized in that the housing (4) is formed in two parts from a housing front part (42) and a housing cover (44). Radial fan according to claim 10,
characterized in that the housing cover (44) is detachably and preferably gas-tightly connected to the housing front part (42). Radial fan according to claim 11,
characterized in that the housing cover (44) has a circumferential, axial groove (62) into which the housing peripheral wall (6) of the housing front part (42) engages with its end edge (66), preferably with the interposition of a seal (64). Radial fan according to claim 10 to 12,
characterized in that the housing cover (44) is connected to the front housing part (42) via at least two, preferably three, snap-fit connections (70) which are arranged uniformly distributed over the circumference of the housing (4). Radial fan according to claim 13,
characterized in that each interlocking connection (70) has a latching arm (72) which extends axially from the housing cover (44) over the peripheral wall (6) and which, with a latching edge (74), has a radial shoulder (76) of the peripheral wall (6 ) engages positively behind. Radial fan according to claim 14,
characterized in that the or each radial extension (74) of the peripheral wall (6) has an inclined surface (80) on its side facing the housing cover (44). Radial fan according to one or more of claims 1 to 15,
characterized in that the rear cover plate (24) of the impeller (20) has a hub (21) connected in a rotationally fixed manner to the drive shaft (22) by means of a radial grub screw (82) or a latching connection. Radial fan according to one or more of claims 1 to 16,
characterized in that the drive shaft (22) on its side facing away from the impeller (20) is connected to a rotor of an electric motor (30) fastened to the rear housing end wall (10), in particular a collectorless DC motor. Radial fan according to one or more of claims 1 to 17,
characterized in that the impeller (20) is designed as a one-piece plastic molding. Radial fan according to one or more of claims 1 to 18,
characterized in that the housing (4) consists of metal. Radial fan according to one or more of claims 1 to 19,
characterized in that the housing front part (42) consists of die-cast aluminum. Radial fan according to one or more of claims 1 to 20,
characterized in that the housing cover (44) consists of deep-drawn sheet metal, preferably fire-aluminum sheet. Radial fan according to one or more of claims 1 to 21,
characterized in that the impeller (20) has forward curved blades (26).

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