EP4276313A1 - Spiral housing for a radial fan and radial fan - Google Patents

Abstract

The invention relates to a spiral casing (12) for a radial fan (10), with a receiving area (14) in which a fan wheel (16) can be arranged, with a spiral channel (22) which extends at least in a circumferential direction (42). extending longitudinal region of the spiral channel (22) in the circumferential direction (42), which enlarges flow cross-section (24), and with a side part (26) delimiting the receiving region (14), which has an axial suction opening (28) through which the air from the Fan wheel (16) which can be arranged in the receiving area (24) can be sucked in in the axial direction (20) and can therefore be sucked into the spiral housing (12). The side part (26) comprises an opening edge region (30) surrounding the suction opening (28). The side part (26) comprises a wall region (32) which adjoins the opening edge region (30) in the radial direction (50) and which, when viewed in the circumferential direction (42), has a course which increases the flow cross section in the circumferential direction (42) such that respective axial surfaces (34, 36) of the opening edge region (30) and the wall region (32) run in the same, first plane.

Description

The invention relates to a spiral casing for a radial fan according to the preamble of claim 1. The invention further relates to a radial fan with such a spiral casing.

The WO 2017/036668 A1 A spiral casing of a radial fan can be seen as known, with a flow cross-sectional area that increases in the circumferential direction around a fan wheel that can be arranged on an axial central axis.

The object of the present invention is to create a spiral housing for a radial blower and a radial blower with such a spiral housing, so that a particularly efficient operation of the radial blower can be realized.

This object is achieved by a spiral casing with the features of patent claim 1 and by a radial fan with the features of patent claim 7. Advantageous embodiments with useful developments of the invention are specified in the remaining claims.

A first aspect of the invention relates to a spiral casing for a radial fan. The spiral casing has a receiving area, which is thus limited, in particular directly, by the spiral casing. In the receiving area, a fan wheel can be arranged to be rotatable about a fan wheel rotation axis relative to the spiral casing, the fan wheel rotation axis running in the axial direction of the fan wheel and thus in the axial direction of the spiral casing, thus with the axial direction of the Fan wheel and thus coincides with the axial direction of the volute casing. Thus, the axial direction of the fan wheel coincides with the axial direction of the volute casing. The spiral casing has a spiral channel through which air can flow, which extends at least essentially spirally around the receiving region in the circumferential direction of the spiral casing and the receiving area, which extends around the axial direction of the spiral casing. By means of the spiral channel, the air conveyed by the fan wheel can be removed from the receiving area and thus from the fan wheel, that is, carried away. The spiral channel has a flow cross section through which the air can flow, which increases at least in a length region of the spiral channel in the circumferential direction of the spiral casing extending around the axial direction of the spiral casing and thus of the receiving area, the length region increasing in the circumferential direction of the spiral casing extending around the axial direction of the spiral casing and thus the recording area, also known as the recording room. The spiral casing has a side part that at least partially, in particular directly, delimits the receiving area. The side part has an axial suction opening, through which the air can be sucked in by the fan wheel that can be arranged or arranged in the receiving area in the axial direction of the spiral housing and thus of the fan wheel and can thereby be sucked into the spiral housing. The axial direction of the spiral casing and the fan wheel runs in the axial direction of the suction opening, the fan wheel conveying the air by rotating the fan wheel in particular about the fan wheel rotation axis relative to the spiral casing and thereby sucking in the air in the axial direction of the spiral casing and thus the suction opening and through the suction opening can convey through and subsequently into the spiral casing, especially into the receiving area. Thus, during operation of the radial fan, during whose operation the fan wheel is rotated about the fan wheel rotation axis relative to the volute housing, whereby the fan wheel conveys the air, the fan wheel is conveyed in the axial direction of the fan wheel and thus in the axial direction of the volute housing by means of the fan wheel Air flows towards it, and the air conveyed by the fan wheel flows in the radial direction of the fan wheel from the fan wheel and into the spiral channel. As a result, the air conveyed by the fan wheel flows through the spiral channel and thus through the flow cross section through the spiral channel.

The side part has an opening edge region surrounding the suction opening, in particular in the circumferential direction of the spiral casing, which extends completely around the suction opening, for example in the circumferential direction of the spiral casing, that is to say over 360 degrees. When we talk about the circumferential direction below, this is to be understood as meaning the circumferential direction of the spiral casing and thus the circumferential direction of the receiving area, unless otherwise stated. In particular, the suction opening is, for example, directly limited to the outside by the opening edge region over its complete, circumferential extension in the radial direction of the suction opening and thus in the radial direction of the fan wheel. The opening edge region is therefore a first wall region of the side part, the first wall region preferably being a solid and preferably inherently rigid, that is to say dimensionally stable.

The side part also has a second wall region which adjoins the opening edge region in the radial direction of the suction opening and thus in the radial direction of the spiral casing towards the outside and which, for example, has the spiral channel, in particular the flow cross section, in particular in the axial direction of the spiral casing and thus the suction opening. at least partially, especially directly, limited. The suction opening has a passage direction which coincides with the axial direction of the suction opening and thus with the axial direction of the spiral casing. The air can flow through the intake opening along the direction of passage if the air is conveyed by means of the fan wheel. The passage direction and thus the axial direction of the suction opening, which coincides with the passage direction of the suction opening, run, for example, perpendicular to a plane in which the suction opening extends.

The second wall region is preferably designed as a solid body and most preferably inherently rigid. For example, the first wall region (opening edge region) and the second wall region are formed in one piece with one another, that is to say formed by a single piece.

Viewed in the circumferential direction, the second wall region has a course which increases the flow cross section in the circumferential direction in such a way that respective axial surfaces of the opening edge region and the second wall region run in the same first plane, in particular perpendicular to the axial direction. In other words, the second wall region has a course that extends in the circumferential direction and increases the flow cross section in the circumferential direction, such that respective axial surfaces of the opening edge region and the second wall region run in the same, first plane. Thus, for example, the axial surface of the second wall region is spaced from the axial surface of the opening edge section in a first longitudinal section running in the circumferential direction in the axial direction of the spiral housing and thus the suction opening. Since the second wall region increases the flow cross section in the circumferential direction, for example, the second wall region, viewed in the circumferential direction, increases in the axial direction, in particular successively, so that, for example, a second length section of the axial surface of the second wall region adjoins the first length section, in particular in the circumferential direction, in the same, First level runs or is arranged like the axial surface of the opening edge region, the axial surface of which is arranged, for example, over its entire extent, in particular in the circumferential direction, in the first plane.

In order to be able to realize particularly advantageous flow conditions in the spiral casing, so that a particularly efficient, in particular energy-efficient, operation of the radial blower can be achieved, it is provided according to the invention that the side part extends over the respective, entire, circumferentially extending extents of the opening edge region and the second wall region has an intermediate region arranged in the radial direction between the opening edge region and the second wall region, the further axial surface of which is arranged in the radial direction of the spiral housing and thus the suction opening between the axial surfaces of the opening edge region and the second wall region over the entire, circumferentially extending extent of the intermediate region in the same further plane, spaced in the axial direction from the first plane and from the axial surfaces of the opening edge region and the second wall region. The intermediate area is also referred to as the intermediate wall area.

The intermediate region is a third wall region, which is preferably a solid and most preferably inherently rigid. In particular, it is conceivable that the first wall region, the second wall region and the third wall region are formed in one piece with one another, and are therefore formed from a single piece or are formed by a single piece, that is to say by a monoblock. In other words, in comparison to conventional solutions, it is not provided that the second wall region adjoins the opening edge region directly to the outside in the radial direction of the spiral casing and thus in the radial direction of the suction opening, but rather in the radial direction of the spiral casing and thus in the radial direction of the suction opening, the intermediate wall area is arranged between the opening edge area and the second wall area, specifically viewed in the circumferential direction of the spiral housing between the respective, entire, circumferentially extending extents of the opening edge area and the second wall area.

The further axial surface of the intermediate region is arranged in the same, further plane over the entire circumferential extent of the intermediate region and thus the further axial surface of the intermediate region, with the further plane preferably running parallel to the first plane. Most preferably, the first plane and the further plane run perpendicular to the axial direction of the spiral casing and thus the suction opening. In addition, the further plane is spaced in the axial direction from the first plane, from the axial surface of the opening edge region and from the axial surface of the second wall region, so that viewed in the circumferential direction there is no point, that is, no point and no region, at which or in which the further axial surface and the axial surface of the opening edge region run in the same plane and so that, viewed in the circumferential direction, there is no point, point or region at which or in which the further axial surface and the axial surface of the second wall region run in the same plane . The further plane and thus the further axial surface of the intermediate region are always spaced in the axial direction in front of the axial surfaces of the opening edge region and the second wall region over the entire circumferential extent of the intermediate region and thus the further axial surface. In particular, it is provided that the axial surface of the opening edge region extends over the entire circumferential direction extending extension of the opening edge area runs in the same, first plane.

In order to be able to realize particularly advantageous flow conditions in a particularly space-saving manner, it is provided in a further embodiment of the invention that the further plane in the axial direction of the spiral casing and thus the suction opening towards the receiving space (receiving area) from the first level and from the axial surfaces of the Opening edge area and the second wall area are spaced apart, and therefore set back.

A further embodiment is characterized in that the spiral channel is at least partially delimited in the axial direction directly by the second wall region, whereby particularly good flow conditions and thus particularly efficient operation of the radial fan can be achieved.

It has proven to be particularly advantageous if the spiral channel is delimited in the axial direction directly by the second wall region, at least in the length region mentioned, whereby the air can be guided particularly advantageously, in particular in a particularly streamlined manner.

In a further, particularly advantageous embodiment of the invention, the spiral channel is partially delimited in the axial direction directly by the intermediate region, whereby the air can be guided in a particularly streamlined manner by means of the side part. This ensures particularly efficient, particularly energy-efficient, operation of the radial fan.

In order to avoid excessive turbulence and thus to be able to realize a particularly efficient operation, it is provided in a further embodiment of the invention that the opening edge region, the intermediate region and the second wall region are formed in one piece with one another, and are therefore formed from a single piece. In other words, it is preferably provided that the opening edge region, the intermediate region and the second wall region are not formed from a plurality of separately formed and interconnected components and are therefore composed, but preferably the three Wall areas made of a single piece, that is to say made of a monoblock or formed by a monoblock.

For example, the side part is made of a plastic. In particular, the side part can be produced by injection molding, in particular by plastic injection molding.

A second aspect of the invention relates to a radial fan which has a spiral casing according to the first aspect of the invention and said fan wheel, which is rotatably arranged in the receiving area about the fan wheel axis relative to the spiral casing and thus relative to the side part. Advantages and advantageous refinements of the first aspect of the invention are to be viewed as advantages and advantageous refinements of the second aspect of the invention and vice versa.

In order to be able to realize a particularly efficient operation of the radial fan, it is provided in an advantageous embodiment of the second aspect of the invention that the fan wheel is at least partially overlapped by the intermediate region in the axial direction outwards. This allows particularly advantageous flow conditions to be achieved.

In order to be able to guide the air in a particularly streamlined manner and thus to be able to realize particularly efficient operation of the radial fan, it is provided in a further embodiment of the invention that the fan wheel is at least partially overlapped by the opening edge region in the axial direction outwards.

Finally, it has proven to be particularly advantageous if the fan wheel is arranged without overlapping the second wall region when viewed in the axial direction. In other words, it is preferably provided that the fan wheel is not overlapped by the second wall region when viewed in the axial direction, whereby a particularly flow-efficient guidance of the air can be achieved.

Further advantages, features and details of the invention result from the following description of a preferred exemplary embodiment and based on the drawing. The features and combinations of features mentioned above in the description as well as the features and combinations of features mentioned below in the description of the figures and/or shown in the figures alone can be used not only in the combination specified in each case, but also in other combinations or on their own, without the scope of to abandon invention.

Fig. 1

eine schematische Draufsicht eines Radialgebläses, mit einem Spiralgehäuse und mit einem Lüfterrad; und

Fig. 2

ausschnittsweise eine schematische Schnittansicht des Radialgebläses.

The drawing shows in:

Fig. 1

a schematic top view of a radial fan, with a spiral casing and with a fan wheel; and

Fig. 2

a partial schematic sectional view of the radial fan.

In the figures, identical or functionally identical elements are provided with the same reference numerals.

Fig. 1 shows a schematic top view of a radial fan 10, also known as a fan, which can be used, for example, in a household appliance, in particular in an extractor hood for a hob. Particularly good when viewed together with Fig. 2 It can be seen that the radial fan 10 has a spiral casing 12. The spiral casing 12 has a receiving area 14, which is delimited, in particular directly, by the spiral casing 12. The radial fan 10 has a fan wheel 16, which is a radial fan wheel. The fan wheel 16 can be rotated about an axis of rotation 18 relative to the spiral housing 12, the axis of rotation 18, also referred to as the fan wheel rotation axis, running in the axial direction of the fan wheel 16, and therefore in this case coinciding with the axial direction of the fan wheel 16. The axial direction of the fan wheel 16 and thus of the spiral casing 12 and the radial fan 10 as a whole is in Fig. 2 illustrated by a double arrow 20. The axis of rotation 18 and thus the axial direction of the spiral casing 12, the fan wheel 16 and the radial fan 10 as a whole run perpendicular to the image plane of Fig. 1 .

Out of Fig. 2 It can be seen that the spiral housing 12 has a spiral channel 22, which, for example, runs spirally around the receiving area 14 in the circumferential direction of the spiral housing 12 and the receiving area 14, which runs around the axis of rotation 18. Air can flow through the spiral channel 22 and is to be conveyed by means of the fan wheel 16 or is conveyed during operation of the radial fan 10. The spiral channel 22 has a flow cross section 24 through which the air conveyed by means of the fan wheel 16 can flow, which, for example, in the circumferential direction of the spiral housing 12 and thus of the radial fan 10, the receiving area 14 and the fan wheel 16 at least essentially spirally around the receiving area 14 and thus extends around the fan wheel 16. The flow cross section 24 increases in the circumferential direction at least in a circumferential length region of the spiral channel 22. In other words, the flow cross section 24 becomes larger in the circumferential direction at least in the mentioned length range, the length range running in the circumferential direction. During the aforementioned operation of the radial fan 10, the fan wheel 16 is rotated about the axis of rotation 18 relative to the spiral housing 12, for example by means of an electric motor. As a result, the said air is conveyed by means of the fan wheel 16, which flows against the fan wheel 16 at least substantially in the axial direction during operation and flows out of the fan wheel 16 at least essentially in the radial direction and is subsequently conveyed through the spiral channel 22 by means of the fan wheel 16 is and thus flows through the spiral channel 22 and thus the flow cross section 24. The air is thus conveyed away from the receiving area 14 and thus away from the fan wheel 16 by means of the spiral channel 22.

The spiral casing 12 has a side part 26, which at least partially, in particular directly, delimits the receiving area 14. The side part 26 is preferably designed in one piece, and is therefore formed from a single piece. The side part 26 has an axial suction opening 28, the axial direction of which coincides with the axial direction of the fan wheel 16 and thus of the spiral housing 12 and the radial fan 10 as a whole. Via the axial suction opening 28, the air can be sucked in by the fan wheel 16 arranged in the receiving area 14 in the axial direction of the spiral housing 12, the fan wheel 16 and the suction opening 28 and thus conveyed through the suction opening 28 and subsequently into the spiral housing 12, in particular into the receiving area 14, is sucked in and thus conveyed into it. Thus, the air conveyed and thus sucked in by means of the fan wheel 16 flows through the suction opening in the axial direction of the suction opening 28, with the air flowing through the suction opening 28 flowing towards the fan wheel 16 in the axial direction of the fan wheel 16 and thus in the axial direction of the suction opening 28. The side part 26 has an opening edge region 30, which in the present case extends completely around the suction opening 28 in the circumferential direction of the spiral housing 12 and thus the suction opening 28 and delimits the suction opening 28, in particular directly. The side part 26 also has a wall area 32. The opening edge region 30 is a first wall region of the side part 26, so that the wall region 32 is also referred to as a second wall region. The wall area 32 adjoins the opening edge area 30 in the radial direction of the spiral housing 12 and thus of the fan wheel 16 and the suction opening 28, which will be explained in more detail below. When viewed in the circumferential direction of the spiral housing 12, the wall region 32 has a course which increases the flow cross section 24 in the circumferential direction such that respective axial surfaces 34 and 36 of the opening edge region 30 and the wall region 32 run in the same, first plane, which are perpendicular to the axial direction and thus perpendicular runs to the axis of rotation 18. The axial surface of the opening edge area 30 is designated 34 and the axial surface of the wall area 32 is designated 36. It can be seen that the spiral channel 22, in particular the flow cross section 24, is at least partially delimited in the axial direction directly by the wall region 32. In the right half of Fig. 2 the axial surface 36 is set back relative to the axial surface 34 in the axial direction towards the receiving area 14 or towards the spiral channel 22. In other words, the axial surface 36 is in the right half of Fig. 2 deeper than the axial surface 34. In the left half of Fig. 2 However, the axial surface 36 is higher in the axial direction and thus along the axis of rotation 18 than the axial surface 34, in other words the axial surface 36 projects beyond the axial surface 34 in the axial direction and away from the spiral channel 22 or from the flow cross section 24. Thus, so to speak, the axial surface 36 rises in the circumferential direction of the spiral housing 12, whereby the flow cross section 24 increases, at least in the length range mentioned, and therefore becomes larger.

In Fig. 1 is an angular range denoted by α, with an initial length range 38 of the wall area 32 extending in the circumferential direction over the angular range α, specifically away from a housing tongue 40 of the spiral casing 12. In other words, the initial length region 38 extends from the housing tongue 40 of the spiral casing 12 in the circumferential direction of the spiral casing 12 over the angular range a. The circumferential direction of the spiral casing 12 and thus of the receiving area 14, the fan wheel 16 and the suction opening 28 runs around the axial direction and thus around the axis of rotation 18 and is in Fig. 1 illustrated by an arrow 42. The wall region 32 is spaced apart from the opening edge region 30 in the axial direction at least or exclusively in the initial length region 38. In other words, the axial surface 36 is spaced in the axial direction from the axial surface 34 at least in the initial length region 38 and is set back in particular towards the spiral channel 22. In Fig. 1 For example, a further length region 44 of the wall region 32 is shown which adjoins the initial length region 38 in the circumferential direction. For example, the axial surface 36 of the wall region 32 is arranged in the same, first plane as the axial surface 34 of the opening edge region 30, at least in the further length region 44.

In order to be able to realize a particularly efficient operation of the radial fan 10, the side part 26 has a space between the respective, entire, circumferentially extending extents of the opening edge region 30 and the wall region 32 in the radial direction of the spiral housing 12, the fan wheel 16 and the suction opening 28 the opening edge region 30 and the wall region 32, also referred to as the intermediate wall region, the intermediate region 46, the further axial surface 48 of which is arranged in the radial direction between the axial surfaces 34 and 36 of the opening edge region 30 and the wall region 32 over the entire, circumferentially extending extent of the intermediate region 46 and thus the axial surface 48 runs in the same further plane, spaced apart in the axial direction from the first plane and from the axial surfaces 34 and 36 of the opening edge region 30 and the wall region 32, which preferably runs parallel to the first plane and / or perpendicular to the axial direction. The radial direction of the spiral casing 12 and thus the suction opening 28 and the fan wheel 16 is in Fig. 1 illustrated by a double arrow 50.

Particularly good looking Fig. 2 It can be seen that the further plane and thus the axial surface 48 is spaced in the axial direction from the first plane and from the axial surfaces 34 and 36 of the opening edge region 30 and the wall region 32 to the receiving area 14, also referred to as the receiving space, or to the spiral channel 22. The spiral channel 22, in particular the flow cross section 24, is at least partially delimited in the axial direction directly by the wall region 32. Furthermore, it is provided that the spiral channel 22, in particular the flow cross section 24, is delimited directly by the wall region 32 in the axial direction, at least in the previously mentioned length regions. Furthermore, it is provided that the spiral channel 22, in particular the flow cross section 24, is partially delimited in the axial direction directly by the intermediate region 46. The fan wheel is at least partially overlapped in the axial direction outwards by the intermediate region 46. In addition, the fan wheel 16 is at least partially overlapped in the axial direction outwards by the opening edge region 30. It is also provided that the fan wheel 16 is arranged without overlapping the wall region 32 when viewed in the axial direction. This makes it possible to create particularly advantageous flow conditions so that particularly efficient operation can be achieved.

Claims (10)

Spiral housing (12) for a radial fan (10), with a receiving area (14) in which a fan wheel (16) can be rotatably arranged, with a spiral channel (22) through which air can flow, which is located at least in a circumferential direction (42). extending longitudinal region of the spiral channel (22) in the circumferential direction (42), which enlarges the flow cross section (24) through which the air can flow, and with a side part (26) which at least partially delimits the receiving region (14), which has: - an axial suction opening (28), through which the air can be sucked in in the axial direction (20) by the fan wheel (16) which can be arranged in the receiving area (24) and thereby sucked into the spiral housing (12), - an opening edge region (30) surrounding the suction opening (28), and - a wall region (32) which adjoins the opening edge region (30) in the radial direction (50) and which, when viewed in the circumferential direction (42), has a course which increases the flow cross section in the circumferential direction (42) in such a way that respective axial surfaces (34, 36) the opening edge area (30) and the wall area (32) run in the same, first plane, characterized in that
the side part (26) has an intermediate region arranged in the radial direction (50) between the opening edge region (30) and the wall region (32) over the respective, entire extents of the opening edge region (30) and the wall region (32), which run in the circumferential direction (42). (46), whose further axial surface (48) is arranged in the radial direction (50) between the axial surfaces (34, 36) of the opening edge region (30) and the wall region (32) over the entire extent of the Intermediate region (46) runs in the same further plane which is spaced apart in the axial direction (20) from the first plane and from the axial surfaces (34, 36) of the opening edge region (30) and the wall region (32). Spiral casing (12) according to claim 1,
characterized in that
the further plane is spaced in the axial direction (20) towards the receiving region (14) from the first plane and from the axial surfaces (34, 36) of the opening edge region (30) and the wall region (32). Spiral casing (12) according to claim 1 or 2,
characterized in that
the spiral channel (22) is at least partially delimited in the axial direction (20) directly by the wall region (32). Spiral casing (12) according to one of the preceding claims,
characterized in that
the spiral channel (22) is delimited directly by the wall region (32), at least in the length region in the axial direction (20). Spiral casing (12) according to one of the preceding claims,
characterized in that
the spiral channel (22) is partially delimited in the axial direction (20) directly by the intermediate region (46). Spiral casing (12) according to one of the preceding claims,
characterized in that
the opening edge region (30), the intermediate region (46) and the wall region (32) are formed in one piece with one another. Radial fan (10), with a spiral housing (12) according to one of the preceding claims, and with the fan wheel (16) arranged in the receiving area (14). Radial fan (10) according to claim 7,
characterized in that
the fan wheel (16) is at least partially overlapped outwards in the axial direction (20) by the intermediate region (46). Radial fan (10) according to claim 7 or 8,
characterized in that
the fan wheel (26) is at least partially overlapped outwards in the axial direction (20) by the opening edge region (30). Radial fan (10) according to one of claims 7 to 9,
characterized in that
the fan wheel (16), viewed in the axial direction (20), is arranged without overlapping the wall region (32).

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