DE102020119881A1 - Tube fan designed as a radial fan - Google Patents

Abstract

The invention relates to a tubular fan (1), in particular designed as a radial fan with a motor (10) and a radial impeller (11), comprising a housing with an intake shell (2) on the intake side, which defines an intake section (52) and the radial impeller (11) and a blow-out shell (3) on the blow-out side, which defines a blow-out section (53), a shell-shaped motor mount (5) being arranged in the blow-out shell (3), and a continuous Flow channel (20) to the blow-out section (53) is formed, through which a flow (S) generated by the radial impeller (11) during operation is guided.

Description

The invention relates to a tube fan, in particular designed as a radial fan with a motor and a radial impeller.

Pipe fans are used to create an air flow through the pipe arrangement within a pipe arrangement with a predetermined pipe diameter. A distinction is made between so-called in-line tube fans, in which the maximum housing diameter of the tube fan corresponds to that of the tube diameter of the tube arrangement. Axial fans and diagonal fans in particular are used for this application. Your advantage lies in the compact design with good flow control. However, they do not reach the pressure and efficiency of a centrifugal fan. This is why axial fans and diagonal fans are used for high volume flows at low pressures.

When using a radial fan that sucks in axially and blows out radially to achieve higher pressures, the housing diameter of the housing accommodating the radial fan is always significantly larger than the tube diameter of the tube arrangement. An in-line variant is therefore not possible with radial fans.

The invention is expressly aimed at a tubular fan, in particular designed as a radial fan. It is known in the prior art to construct the housing in several parts and to integrate the motor mount for the motor of the radial fan in the housing part on the outlet side. The centrifugal impeller of the centrifugal fan promotes a volume flow that is blown unaffected into the outlet-side housing part and then into the adjacent pipe arrangement. This leads to recirculation zones and separation of the flow in the outlet-side part of the housing, which have a negative effect on both efficiency and noise.

The invention is therefore based on the object of providing a tubular fan designed as a radial fan whose flow guidance is improved in such a way that its efficiency is increased and at the same time noise is reduced.

This object is achieved by the combination of features according to claim 1.

According to the invention, a tubular fan is proposed, in particular designed as a radial fan with a motor and a radial impeller, which comprises a housing with an intake shell on the intake side, which defines an intake section and accommodates the radial impeller, and an outlet shell on the outlet side, which defines an outlet section. A cup-shaped motor mount for fixedly receiving the motor is arranged in the exhaust cup. A continuous flow channel to the blow-out section is formed between the motor mount and the blow-out shell, through which a flow generated by the radial impeller during operation is guided.

As in the prior art, the casing of the duct fan is attached to the adjacent duct arrangement through which the flow is to pass. The suction shell and exhaust shell determine the larger diameter compared to the pipe arrangement. The respective shell shape of the suction shell and exhaust shell provides the widening to an enlarged diameter and the subsequent narrowing with the reduction of the diameter to that of the pipe arrangement, viewed in the direction of flow. The also at least partially shell-shaped motor mount in the exhaust shell creates the flow channel for the flow generated by the radial fan and thus a defined flow guide from the radial impeller to the exhaust section, which minimizes recirculation zones and flow separations. This has a positive effect on efficiency and reduces noise.

An advantageous development of the tubular fan also provides that a plurality of guide struts distributed in the circumferential direction are arranged in the flow duct. The guide struts are preferably designed as radial struts with guide surfaces for the flow extending through the flow channel.

An advantageous embodiment of the tube fan is one in which the guide struts extend from an outer lateral surface of the motor mount to an inner wall surface of the exhaust shell and subdivide the flow duct into a plurality of individual ducts in the circumferential direction. Due to the radial extension of the guide struts from wall to wall, the individual channels are closed and are preferably only brought together again in the blow-out section.

A preferred variant is characterized in that the guide struts are formed in one piece on the motor mount. This reduces the number of parts and the effort required to assemble the motor mount on the outer shell.

In the prior art, the engine mount could often be formed in one piece with the exhaust shell. However, in the case of the present tube fan, the motor mount is made out as a separate part guided. Nevertheless, for an advantageous and simple assembly option, it is provided that receiving grooves are provided on the exhaust shell for the fixed insertion of fastening webs formed on the motor mount. The motor mount can thus be fixed in position in the blow-out shell, but is at the same time releasably fastened. The receiving grooves are preferably formed in a tubular end section of the blow-out shell, which defines the blow-out section. In this area, the receiving grooves have practically no effect on the flow.

A design variant of the tube fan is particularly advantageous, in which the fastening webs on the motor mount are formed by the guide struts. The guide struts thus assume both the function of guiding the flow through the flow channel and of fastening the motor mount to the exhaust shell.

The flow channel between the exhaust bowl and the motor mount is ensured by their two bowl-shaped wall sections. The motor mount comprises a shell with a cross section that tapers in the direction of flow, the taper substantially corresponding to that of the outer shell, so that the flow channel has a substantially constant flow width. However, the guide struts preferably extend in the axial direction of flow beyond the shell of the motor mount that forms the flow channel, in particular as far as into the blow-out section and thus guide the flow into the adjacent pipe arrangement.

On the axial side facing the radial impeller, the shell of the motor mount that forms the flow channel has, in an advantageous embodiment, an axial projection running around in the circumferential direction. The axial projection defines an inlet section of the flow channel and protrudes axially in the direction of the radial impeller relative to the guide struts. In other words, the guide struts begin their extension in the flow channel at an axial distance from an axial outer edge of the shell of the motor mount.

An aerodynamically favorable design of the tubular fan also provides that the guide struts are curved in sections in the circumferential direction. A course curved in an arc shape is particularly preferred. The curved course is provided in particular in the area of the engine mount where the shell is located. In the subsequent section, the guide struts end running in the axial direction of flow, i.e. parallel to the axis of rotation of the centrifugal fan.

The noise reduction of the tube fan is positively reinforced by a further development in which a wall section of the shell of the motor mount forming the flow channel is designed to be perforated with through-holes. Soundproofing insulating material can then be introduced into the shell. In a favorable embodiment, the shell of the motor mount has an axially central motor base for mounting the motor and defines a receiving space between an inner wall surface of the perforated wall section and the motor base. This receiving space can be used in the same way for arranging noise-damping insulating material.

A further development for noise reduction of the tubular fan, particularly in the area of the outer shell, is also provided. For this purpose, in the region of the flow duct, the exhaust shell has a radial widening between the guide struts, viewed in the circumferential direction, which is designed to accommodate noise-damping insulating material. In an axial top view, a kind of flower shape results from the widening of the exhaust shell distributed in the circumferential direction. The radial expansions follow the extension between each two of the guide struts and are therefore preferably likewise curved or twisted in an arc shape in the circumferential direction. The noise-damping insulating material is preferably injected directly into the radial expansions on the exhaust shell. Insulating foam, for example, can be used as the insulating material.

For an advantageous inflow of the air flow generated by the radial impeller into the flow channel, the tube fan is characterized in that a maximum outside diameter of the shell of the motor mount on the intake side is larger than an outside diameter of the radial impeller. Furthermore, an embodiment is favorable in which the suction section defines an inlet nozzle which extends in the axial direction of flow into an inlet opening of the radial impeller.

In the case of the tubular fan, an advantageous further development also provides that the intake shell and the outlet shell can be fixed to one another by means of a fastening device when placed on top of one another and thereby define a position of the motor mount in the outlet shell. For example, clamps or a bayonet catch can be used as a fastening device. In particular, the engine mount is positioned between the intake shell and the exhaust shell and is also fixed when they are fixed.

• 1 eine Ausführungsvariante des erfindungsgemäßen Rohrventilators in einer Schnittansicht.

Other advantageous developments of the invention are characterized in the dependent claims or are presented in more detail below together with the description of the preferred embodiment of the invention with reference to the figure. It shows:

• 1 an embodiment of the tube fan according to the invention in a sectional view.

In 1 a duct fan 1 designed as a radial fan is shown in a cutaway view. The in-line fan 1 comprises two housing parts designed as an intake shell 2 on the intake side and a discharge shell 3 on the outlet side. The flow diameter of the intake shell 2 and the outlet shell 3 is also significantly larger for the radial fan due to the design. The radial fan with its motor 10 and its radial impeller 11 driven by the motor 10 is arranged in the intake shell 2 . The radial impeller 11 comprises a cover disk, a base disk and impeller blades running between them. In operation, the radial impeller 11 draws in a flow S axially through the suction section 52 and blows it out radially in the direction of the inner wall surface of the suction cup 2 .

The motor 10 is fastened to the motor base 22 in the center of the axis of the cup-shaped motor mount 5 , which in turn is accommodated and fixed in the exhaust cup 3 . The shell-shaped motor mount 5 comprises the shell 6, on which the central motor base 22 is integrally formed, and the guide struts 4, which are preferably also integrally formed on the shell 6 in the circumferential direction on the outside. Between the shell 6 of the engine mount 5 and the exhaust shell 3 is the continuous one Flow channel 20 is formed to the blow-out section 53, through which the flow S generated by the radial impeller 11 during operation is guided. The flow channel 20 is divided into several individual channels by the guide struts 4 , since the guide struts 4 extend continuously from the outer surface of the shell 6 of the motor mount 5 to the inner wall surface of the exhaust shell 3 . In the downstream area of the shell 6, the individual channels are then combined again to form a flow channel. The guide struts 4 extend in the axial direction of flow beyond the shell 6 of the motor mount 5 that forms the flow channel 20 and into the tubular blow-out section 53. On the axial side facing the radial impeller 11, the guide struts 4 are spaced apart from the axial edge of the shell 6 by the axial projection 12 . The axial projection 12 runs parallel to the axis of rotation of the radial fan 11. The inflow into the flow channel 20 is therefore initially only determined by the shell 6 and the outlet shell 3. The flow is guided via the guide struts 4 only within the area of the flow channel 20 in which the shell 6 begins to reduce its cross section.

For this purpose, the guide struts 4 are curved in sections in the circumferential direction. The preferably arcuate curvature 63 is particularly advantageous, but other constant curvatures, including an S-shaped course, can also be provided as required. The direction of curvature is preferably coordinated with the direction of rotation of the radial fan 11. In the blow-out section 53, the guide struts 4 end running parallel to the axial direction of flow. The flow S is guided by the guide struts 4 through the flow channel 20 along the shell 6 of the engine mount 5 and the exhaust shell 3 .

A plurality of receiving grooves 9 are formed in the blow-out section 53 for receiving the guide struts 4 in a fixed manner. The guide struts 4 are inserted into the receiving grooves 9 for mounting the motor mount 5 in the exhaust shell 3 and thus fix the motor mount 5 in the exhaust shell 3. Alternatively, a solution is also included, although not shown, in which the engine mount 5 is independent of the Guide struts 4 fastening webs are arranged or formed, which fix the motor mount 5 in the receiving grooves 9 of the exhaust shell 3. The intake shell 2 and the exhaust shell 3 are placed one on top of the other and fixed to one another by clamps 51 . The motor mount 5 is positioned with a part of the guide struts 4 between the housing parts of the intake shell 2 and the exhaust shell 3, and is also fixed by fastening them and fixed in position. In particular, it is ensured that the guide struts 4 are pushed completely into the receiving grooves 9 when the clamps 51 are fixed.

A wall portion of the shell 6 of the motor mount 5 has a plurality of through holes 8 forming a perforation. The size of the through holes 8 decreases as seen in the flow direction. Noise-damping insulating material (not shown) is introduced into the receiving space 15 between the shell 6 of the motor mount 5 and the motor base 22 in order to minimize the noise generated by the flow along the shell 6 . The perforation through the through gangholes 8 increases the effect of the soundproofing insulation material. In addition, radial widenings 7 are formed on the exhaust shell 3 in the areas between the guide struts 4 , which have a course in the circumferential direction and in the axial direction that corresponds to that of the guide struts 4 . Noise-damping insulating material (at reference number 77, but not shown) is also introduced into the flared portions 7, preferably injection-moulded on. A reduction in noise is thus also achieved at the exhaust tray 3 .

Claims (15)

Tube fan (1), in particular designed as a radial fan, with a motor (10) and a radial impeller (11), comprising a housing with an intake shell (2) on the intake side, which defines an intake section (52) and accommodates the radial impeller (11), and a discharge-side discharge cup (3) defining a discharge portion (53), wherein a cup-shaped motor mount (5) for fixedly receiving the motor (10) is disposed in the discharge cup (3), and between the motor mount (5) and the discharge cup (3) a continuous flow channel (20) is formed to the blow-out section (53), through which a flow (S) generated by the radial impeller (11) during operation is guided. pipe fan after claim 1 , characterized in that in the flow channel (20) a plurality of circumferentially distributed guide struts (4) are arranged. pipe fan after claim 2 , characterized in that the guide struts (4) extend from an outer lateral surface of the motor mount (5) to an inner wall surface of the exhaust shell (3) and divide the flow channel (20) into a plurality of individual channels in the circumferential direction. pipe fan after claim 2 or 3 , characterized in that the guide struts (4) are integrally formed on the engine mount (5). Tube ventilator according to one of the preceding claims, characterized in that receiving grooves (9) are provided on the exhaust shell (3) for the fixed insertion of fastening webs formed on the motor mount (5). Tube fan according to the preceding claim, characterized in that the receiving grooves (9) are formed in a tubular end section of the outlet shell (3) which defines the outlet section (53). pipe fan after claim 5 or 6 , characterized in that the fastening webs are formed by the guide struts (4). Tube fan according to one of the above claims 2 until 7 , characterized in that the guide struts (4) extend in the axial direction of flow over a shell (6) of the motor mount (5) forming the flow channel (20). Tube fan according to the preceding claim, characterized in that the shell (6) of the motor mount (5) forming the flow duct (20) has an axial projection (12) which runs in the circumferential direction and which defines an inlet section of the flow duct (20) and which is opposite the guide struts ( 4) protrudes axially in the direction of the radial impeller (11). Tube fan according to one of the above claims 2 until 8th , characterized in that the guide struts (4) are curved in sections in the circumferential direction, in particular curved in an arc shape, and end running axially in the axial direction of flow. Tube fan according to one of the preceding claims, characterized in that a wall section of a shell (6) forming the flow channel (20) of the motor mount (5) is perforated with through holes (8). Tube fan according to the preceding claim, characterized in that the shell (6) of the motor mount (5) has an axially central motor base (22) for mounting the motor (10) and between an inner wall surface of the perforated wall section of the shell (6) and the motor base ( 22) a receiving space (15) for arranging soundproofing insulation material. Tube fan according to one of the above claims 2 until 12 , characterized in that the exhaust shell (3) in the region of the flow duct (20), viewed in the circumferential direction, has a radial widening (7) between the guide struts (4), which is designed to accommodate noise-damping insulating material. Tube fan according to one of the preceding claims, characterized in that the intake shell (2) and the outlet shell (3) placed on top of each other can be fixed to one another by a fastening device and a posi tion of the engine mount (5) in the exhaust tray (3). Tube fan according to one of the above Claims 8 until 14 , characterized in that an intake-side maximum outer diameter of the shell (6) of the motor mount (5) is larger than an outer diameter of the radial impeller (11).

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