CH680040A5 - Domestic extractor fan with tubular air duct - has radial ventilator at one end, wheel with suction duct, and air outlet - Google Patents

Abstract

The extractor-fan, especially for kitchens, has a tubular air-duct (3) on the input end of which is an air-inlet housing. A radial ventilator (5-8) sucks up the air axially and blows it out radially and is positioned at the output end of the air duct (3). The radial ventilator has a wheel (5) whose suction duct (8) has the same cross-section as the air-duct (3). The radial ventilator is enclosed by an air-guide (12) forming an air outlet (21) with shield (13,14). ADVANTAGE - The domestic extractor-fan is more efficient by being a radial fan sucking in air axially and blowing it out radially.

Description

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The present innovation relates to a ventilation device with a tubular air duct, at the input end of which an air inlet housing is arranged, and with a fan.

Such a ventilation device is offered in many designs for removing polluted air from household kitchens. The known devices mostly use so-called extractor hoods, which can be arranged above the respective cooking areas of kitchens and discharge the air through pipes or fan housings via spiral exhaust air chambers. The spiral exhaust air chambers are used to pass on the air masses ejected by the fan, which, however, is associated with considerable power losses due to the flow resistance. Because of this flow resistance, the known systems are sometimes too weak in terms of performance, so that the desired exhaust air performance is not achieved. Larger fans can be used to increase the ventilation, making the ventilation device very bulky and noisy during operation. Bulky ventilation devices generally do not meet the buyer's taste, so that the larger ventilation devices are generally not used for optical reasons. Thus, in particular household kitchens are usually equipped with poorly performing ventilation devices, which results in unpleasant odors.

It is the object of the present innovation to provide a ventilation device which has a better efficiency.

This object is achieved in a ventilation device of the type mentioned at the outset in that the fan is designed as a radial fan which sucks in the air in the axial direction and blows off in the radial direction, and in that the fan is arranged on the outside at the outlet end of the air duct.

By choosing a radial fan on the outside at the outlet end of the duct instead of an axial fan in the duct, the resistance in the air duct is reduced. The air can flow more freely through the duct, whereby an increased volume flow can be conveyed with the same fan output. In the case of an axial fan arranged in the air duct, the size of the fan wheel, i.e. of the propeller, limited by the size of the channel. A higher performance can then only be achieved by increasing the speed of rotation, which in turn leads to unpleasant noises. The radial fan also has the advantage that it is standing, i.e. when it is not in operation, offers a relatively large flow resistance, since the air which then wants to flow through the air duct has to be redirected several times. It is thus achieved in a simple manner that even in adverse weather conditions there is a relatively high level of security against undesirable drafts in the room to be ventilated. The arrangement of the

The outside of the fan at the outlet end of the air duct also has the advantage that the noise associated with the operation of the fan is generated at a certain distance from the air inlet housing. Since the workplace of the person who wants to use the ventilation device will generally be in the area of the air inlet housing, the user comfort is increased since the new ventilation device works much quieter for the user. The fan can be located far away from the air intake location, for example on the outer wall of the room to be ventilated.

The air duct of the ventilation device is advantageously free of throttling points. This gives favorable resistance values which, as mentioned above, allow a higher volume flow to be delivered with the same fan drive power. The chokes, i.e. The spirals arranged in the state of the art on the pressure chamber side no longer need to be cleaned or kept clean. The polluted air is blown more or less freely into the environment. Nevertheless, as explained above, there is a throttling effect when the fan is at a standstill.

The radial fan particularly advantageously has a fan wheel, the intake duct of which has essentially the same cross-sectional area as the air duct at the end of the duct. The intake duct preferably has approximately 60% to 130% of the cross-sectional area of the outlet of the air duct, which corresponds approximately to the inscribed or circumscribed square of the circle formed by the intake duct of the fan wheel. As a result, the conveyed air flowing through the air duct is not subject to any change in speed when it enters the intake duct of the radial fan from the air duct. These changes in speed require additional energy and generally cause further noise.

In a preferred embodiment, the radial fan is surrounded on the outside by an air guiding device which directs the air flow generated by the radial fan away from the air duct. When installing the ventilation device, the vapors should be blown away from the suction location and not diffuse. This is achieved in a simple manner by the air guiding devices. But even if the ventilation device is installed permanently, for example if the air inlet housing is installed in a household kitchen and the fan is installed on the outer wall of the kitchen, it is advantageous if the exhaust air flow is blown away from the outer wall of the kitchen. This prevents grease and other ingredients in the kitchen air from being deposited on the outer wall.

The air guiding device is advantageously designed as part of a fan housing which is connected to the air duct. The air guiding device then simultaneously offers the fan a certain protection, for example against weather influences.

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The fan housing preferably has the shape of a trapezoid in vertical section and / or horizontal section, the wider end of which is arranged on the side facing away from the air duct and forms an air inlet opening. The oblique sides of the trapezoid serve in a simple manner as an air guiding device.

In a preferred embodiment, a protective shield adjoins the fan housing in the area of the air outlet opening and is angled inward with respect to the fan housing. This results in an even better air flow in one direction. At the same time, the fan is even better protected from the weather. Bending inwards ensures that water that drips on the fan housing due to rain or other influences can flow away easily without adversely affecting the fan or the fan.

It is preferred that the protective shield extends the fan housing and moves the air outlet opening further away from the fan wheel. This enlarges the interior of the fan housing, so that there are fewer spatial restrictions for the size of the radial fan and its mounting. In addition, the exhaust air is guided even better.

The protective shield is advantageously arranged in the region of the lower edge of the air outlet opening approximately horizontally or with a slight downward inclination, a drip nose being provided at its outer end. It is inevitable that in the exhaust air, i.e. the air extracted from the room to be ventilated contains a certain amount of moisture. This is particularly the case when the ventilation device is used to extract cooking fumes over a hotplate. If the exhaust air now hits the housing, it can happen that, due to different temperatures of the air and the housing, part of the moisture condenses on the housing or on the air guiding device and drips downwards. The water can then flow away easily due to the horizontal or slightly downward inclination of the protective shield at the lower end. The drip nose is particularly advantageous if the fan housing is arranged directly on a wall. This will prevent condensation from running down the wall and leaving ugly marks there.

In a preferred embodiment, the stator of the drive motor of the radial fan is mounted on a support plate which is arranged on the side of the radial fan facing away from the air duct, the support plate projecting at least in sections beyond the radial fan and being connected to the housing there in particular with the aid of spacer screws is. This makes assembly easier. In addition, there are no engine elements in the intake air flow, so that the path of the pumped air remains free of Dross-points.

Electrical auxiliary devices are advantageously arranged on the side of the support plate facing away from the radial fan. These auxiliary electrical devices can be starting resistors, capacitors, control and regulating devices or the like, which are used to start or regulate the speed of the engine. Due to the claimed housing construction, these auxiliary devices are cooled indirectly by the air flow of the conveyed air, but are largely protected against contamination.

The support plate for receiving the electrical auxiliary devices is advantageously bent in a U-shaped cross section. The cavity created in this way provides even better protection against the weather.

A substantially uniform circumferential gap is advantageously formed between the support plate and the circumferential protective shield. This provides a large air outlet area from the housing.

The area of the gap is advantageously larger than the cross-sectional area at the end of the air duct. This measure also serves to reduce the flow resistance.

It is particularly advantageous that the area of the gap is at least 50% larger than the cross-sectional area at the end of the air duct. This dimensioning rule has proven to be advantageous for a large part of the ventilation devices according to the innovation.

Preferably, the protective shield and the support plate end essentially in the same plane in the axial direction. This gives the fan housing a closed appearance and reduces the risk of injury from protruding parts.

The innovation is described below with reference to a preferred embodiment in conjunction with the drawing. In it show:

1 is a schematic perspective view of a ventilation device,

2 is a plan view of a fan housing from the direction of the air outlet opening,

Fig. 3 is a cross-sectional view A-B of Fig. 2 and

4 is a cross-sectional view C-D of FIG. 2nd

In Fig. 1, a ventilation device 1 is shown schematically, which sucks in air by means of a radial fan 4 via an air intake housing 2 and an air duct 3 in the form of a tube. The air intake housing 2 can be designed in the form of a conventional kitchen extractor hood. 1, housing parts and fastening means for the fan 4 are omitted for reasons of clarity. The fan 4 has a fan wheel 5 which is driven in the direction of the arrow 24 by a motor 7, the stator of which is mounted in a housing. The rotor 7 of the motor is connected to the fan wheel 5 via a drive plate 6. The fan wheel has two annular disks arranged parallel to one another, which are connected to one another by blades 9. The blades 9 extend in the radial direction approximately over the same distance over which the two circular rings also extend in the radial direction.

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As a result, the fan wheel 5 forms an air intake duct 8, into which air is drawn in from the tube 3 when the motor 7 rotates the fan wheel 5. The drive plate 6 advantageously serves to move the intake duct 8 forward, i.e. on the side facing away from the air duct 3, so that all the air conveyed by the fan wheel 5 is actually sucked out of the air duct 3.

In the illustrated embodiment, the air duct 3 is designed as a tube with a circular cross section, the diameter of which is equal to the diameter of the air intake duct 8. Air that enters the air intake duct 8 from the air duct 3 does not have to change its speed. It is only redirected and outwards, i.e. blown away in the radial direction by the fan wheel 5.

The structural design of the fan device 4 with the assignment of the fan wheel, motor and housing to one another is shown in FIGS. 2 to 4.

The air duct 3 is connected to a connecting piece 10 which leads to the fan wheel 5 up to a short distance. The fan wheel 5 is connected via the drive plate 6 to the rotor of the motor 7, the stator of which is in turn arranged on a carrier plate 20 which projects at least in sections beyond the circumference of the fan wheel 5. In the illustrated embodiment, the carrier plate forms a square, the four corners of which protrude beyond the circumference of the fan wheel 5. At these four corners, the support plate 20 is connected by means of spacer bolts 16, 17 to a housing 11 which is connected to the connecting piece 10. The carrier plate 20 is connected to the spacer-holding boizen 16, 17 via a U-shaped angled plate 18, which one to the outside, i.e. in the direction away from the fan wheel 5, open cavity forms. In this cavity electrical auxiliary devices 22, e.g. a starting resistor, an auxiliary capacitor or a control device. This U-shaped cavity is covered by a cover 19.

The air conveyed by the fan wheel 5 is blown outward in the radial direction by the fan wheel 5. In order to be able to transport the air away from the air duct 3 in a targeted manner, air baffles 12 are provided which direct the air forward, i.e. deflect away from the air duct 3. The air baffles 12 form part of the housing 11, which surrounds the fan. The housing has the shape of a trapezoid in horizontal and vertical cross section, the wider side being arranged on the side of the fan wheel 5 facing away from the air duct 3 and forming an air outlet opening. In order to further improve the air flow, a protective shield 13, 14 is additionally provided, which is attached to the housing 11 and angled inwards. The protective shield 13 has an inclination at the top, left and right in the direction of the axis of rotation of the fan, while the protective shield 14 is arranged at the bottom essentially horizontally or with a slight inclination downward away from the axis of rotation. In addition, a drip nose 15 is arranged on the protective shield below, so that condensed water, which is deposited in the fan housing 11 or on the protective shield 13, can drain off on the protective shield 14 below and drip off via the drip nose 15.

The protective shield 13, 14 extends the housing and moves the air outlet opening further forward, i.e. further away from air duct 3. An air outlet gap 21 is formed between the protective shield 13, 14 and the support plate 20 or between the protective shield 13, 14 and a connecting plate 25 which connects the support plate 20 and the cover 19 to one another. This air outlet gap 21 surrounds the entire support plate 20 and has an approximately constant width d on all four sides of the support plate 20. In one exemplary embodiment, in which the air duct 3 has a cross-sectional area of approximately 180 cm 2, the air outlet gap has a cross-sectional area of approximately 280 cm 2 at a width of d = 4 cm.

The cover 19 and the front end of the protective shield 13, 14 end approximately in the same plane. The front end of the protective shield 13 is still bent outwards, lies practically in the same end plane and forms a stop 23. This stop is of particular value if the fan housing is to be installed in a larger device or in a wall and then serves as a stop for the installation depth.

Claims (16)

Claims 1.Ventilation device for discharging polluted air from rooms, in particular from domestic kitchens, with a tubular air duct, at the input end of which an air inlet housing is arranged, and with a fan, characterized in that the fan is designed as a radial fan (5-8) which the air is sucked in in the axial direction and blows off in the radial direction, and that the fan is arranged on the outside at the outlet end of the air duct (3). 2. Device according to claim 1, characterized in that the air duct (3) is free of throttling points. 3. Device according to claim 1 or 2, characterized in that the radial fan has a fan wheel (5), the intake duct (8) has substantially the same cross-sectional area as the air guide duct (3) at the duct end. 4. Device according to one of claims 1 to 3, characterized in that the radial fan is surrounded on the outside by an air guiding device (12) which guides the air flow generated by the radial fan away from the air duct (3). 5. The device according to claim 4, characterized in that the air guiding device (12) is designed as part of a fan housing (11) which is connected to the air duct (3). 6. The device according to claim 5, characterized in that the fan housing (11) in vertical section and / or horizontal section has the shape of a trapezoid, the wider end of which on the 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 7 CH 680 040 A5 The air duct (3) facing away is arranged and forms an air outlet opening (21). 7. The device according to claim 6, characterized in that the fan housing (11) 4 in the area of the air outlet opening, a protective shield (13, 14) connects, which is angled inwards with respect to the fan housing (11). 8. The device according to claim 7, characterized ge-indicates that the protective shield (13, 14) Fan housing (11) extended and the air outlet opening (21) further away from the fan wheel (5). 9. The device according to claim 7 or 8, characterized in that the protective shield (13, 14) in the region of the lower edge of the air outlet opening (21) is arranged approximately horizontally or with a slight inclination downwards, a drip nose (15 ) is provided. 10. The device according to one of claims 5 to 9, characterized in that the stator (7) of the drive motor of the radial fan is mounted on a support plate (20) which is arranged on the side of the radial fan facing away from the air duct (3), the Carrying plate (20) protrudes at least in sections over the fan wheel (5) and is connected to the housing (11) there in particular with the aid of spacer screws (16, 17). 11. The device according to claim 10, characterized in that on the side facing away from the radial fan of the support plate (20) electrical auxiliary devices (22) are arranged. 12. The apparatus according to claim 11, characterized in that the support plate (18, 20) for receiving the electrical auxiliary devices (22) is bent in a U-shaped cross section. 13. Device according to one of claims 10 to 12, characterized in that a substantially uniform circumferential gap (21) is formed between the support plate (20) and the circumferential protective shield (13, 14). 14. The apparatus according to claim 13, characterized in that the area of the gap (21) is larger than the cross-sectional area at the end of the air duct (3). 15. The apparatus according to claim 14, characterized in that the area of the gap (21) is at least 50% larger than the cross-sectional area at the end of the air duct (3). 16. Device according to one of claims 10 to 15, characterized in that in the axial direction protective shield (13, 14) and support plate (18, 20) end essentially in the same plane. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 5