EP0548761A2 - Throttle device - Google Patents

Abstract

The invention relates to a ventilation throttle device for the adjustment of a gas, in particular air, volume flow, with a throttle body. It is characterised in that the throttle body (2) has a web arrangement (30) which brings about the throttling. <IMAGE>

Description

The invention relates to a ventilation throttle device for setting a gas, in particular air volume flow, with a throttle body.

A large number of differently designed throttle devices for adjusting, in particular also regulating, air volume flows are known in air technology. With the help of a throttle body, the pressure loss coefficient of such a device is fixed or it can be varied as desired.

It is disadvantageous that the known throttle devices often generate relatively loud noises, so that it is often necessary to add a silencer. In special cases it can even happen that an upstream silencer must be used. In addition to the resulting costs, there is the disadvantage that silencers are classified as a potential source of danger because of the mineral fibers they contain and thus the risk of emission of the finest respiratory fibers.

If flaps are used as throttle bodies in the known throttle devices, typically a low-frequency noise occurs at low pressure loss coefficients, which can only be prevented by large-volume silencers. If a perforated diaphragm or a perforated plate is used as the throttle body, it emits a sound spectrum with a higher frequency at comparable pressure loss coefficients, which can be combated relatively effectively by silencers. However, with an uneven flow, which often occurs in air line networks, perforated plates can increase the level by up to 10 dB (decibels). In addition, acoustically favorable, but small hole diameters (up to approx. 3 mm) of the perforated screens tend to clog.

It is known that a multi-stage pressure reduction with the same line cross-section leads to a lower noise relative to a single-stage pressure reduction with the same volume flow and the same total pressure loss. The prerequisite is that the flow can equalize after each throttle stage, otherwise there is a risk of cutting tones. This requirement causes multi-stage throttling devices, e.g. B. perforated plate throttling devices, are correspondingly long in the direction of flow and thus become unwieldy for practical use or are not suitable for certain installation locations. A multi-stage throttling on the smallest space is possible with the well-known filter fleece, the z. B. as mats perpendicular to the direction of flow be arranged in the line cross-section. The pressure energy to be reduced is dissipated into the smallest eddies. The resulting high-frequency noise comes from a multitude of smallest sound sources that are dampened by the tangle of fibers. Due to the good dust absorption and storage, the pressure loss coefficient increases relatively quickly over time. A filter mat of this type is therefore only suitable as a throttle element when extremely clean air is used and, moreover, should be easily accessible for the frequent exchange to be carried out.

The invention is therefore based on the object of providing a throttle device of the type mentioned which causes the lowest possible noise during operation, requires relatively little maintenance and is inexpensive to manufacture.

This object is achieved in that the throttle body has a web arrangement causing the throttling. This web arrangement has webs which bring about a dissipation of pressure energy into the smallest vertebrae. The webs can be formed in particular by sheet metal webs or they are formed by bristles. In the following only bristles will be dealt with, however the explanations relating to bristles should also apply to webs, in particular sheet metal webs and the like. Such bristles have a "self-cleaning effect", which leads to normal contaminants, e.g. B. coming from centrally filtered supply air or from office rooms Exhaust air, not to increase the pressure loss coefficient to an impermissible value. In the case of the known nonwovens, due to their dirt-trapping effect, a particle build-up can be found in the crossing points of the fibers, which leads to the formation of dust bridges, which creates dust cakes which drastically increase the pressure loss coefficient. This danger does not exist in the throttle device according to the invention; nevertheless, only a noise development corresponding to the known fleeces can be determined. The throttle bodies according to the invention, provided with bristles, can be manufactured inexpensively in a simple manner. In particular, they can also form "control flaps".

In a further development of the invention it is provided that the bristles are arranged in rows next to one another. The individual bristles are preferably arranged approximately parallel to one another.

However, it is also possible for a plurality of adjacent bristles each to form a tuft of bristles, the individual tufts of bristles being arranged in rows next to one another. This leads to the formation of a row of bristles.

According to a preferred embodiment, the throttle body is provided with bristles in such a way that - seen in the direction of flow - a plurality of bristles lie one behind the other. This leads to rows of bristles arranged in several stages, which, depending on the position of the air flow to be throttled, lead to a corresponding one Lead pressure loss coefficient, do not tend to clog due to contamination and have noise damping properties similar to the known nonwovens.

It is preferably provided that the bristles are held at one end in a holding element and that the other end of the bristles each forms a free end. Alternatively, it is also possible that both ends of the bristles are each fastened to a holding element or to a common holding element.

The "self-cleaning effect" is improved if the volume flow to be throttled flows across the bristles transversely to their longitudinal extent. In particular, the inflow forms an acute angle with the longitudinal extension of the bristles. With this configuration, the bristles are hardly prone to contamination. The inflow is preferably carried out in such a way that it first hits the held or clamped end of the bristles and only then — viewed in the direction of flow — meets the free end of the bristles.

The bristles can preferably be held by a clamping device, in particular a clamping strip, preferably at one end.

According to a further embodiment it is provided that the throttling bristles - depending on the desired pressure loss coefficient and / or the desired design - in one stage or in several stages in the direction of flow are arranged one behind the other. The multistage can either result continuously, as viewed in the flow direction, in that a plurality of bristles are arranged one behind the other, or bristle groups are arranged at a distance from one another in the flow direction (for example in the form of tufts).

The arrangement and / or position of the bristles can be predefined so that a fixed pressure loss coefficient is established. Alternatively, however, it is also possible for the bristles to be adjustable, in particular pivotable, so that an optional setting of the pressure loss coefficient is possible. It can be provided that the bristles are only set during assembly and then remain at this set value, so that the desired pressure loss coefficient is thereby brought about. However, it can also be provided that the bristles are adjustable, depending on the operating parameters that are currently desired. that is, their respective location or position is changed depending on the desired operating point. This allows z. B. solve control or regulation tasks.

It is preferably provided that the holding element is displaceable for adjusting the bristles.

A relatively large pressure loss coefficient results when the free end regions of adjustable, in particular pivotable, bristles in the adjusting end region are against an air flow limiting wall or the like. occur that the bristles condense, in particular bend.

The bristles are preferably made of plastic or metal wires. Polyethylene, brass or stainless steel have proven themselves as the material for the bristles. The cross section of the bristles is preferably circular.

According to a preferred embodiment, the bristles form a choke brush, i.e. H. the throttle body has a brush-like appearance. If the throttle body has a row of bristles or a row of bristle tufts, the throttle brush assumes an approximately comb-like appearance.

Alternatively, the bristles can also form a conical throttle element, the cone tip of which is flowed against by the air flow.

If the throttle brush has two rows of bristles, there is an approximately double-comb-like structure. The two rows of bristles preferably enclose a downstream angle which is <180 °. The inflow takes place in such a way that the air flow first hits the tip of the said angle and only then hits the free ends of the bristles further downstream.

According to a further exemplary embodiment, it is provided that - viewed in the direction of flow - the bristles form a bristle screw, ie they meet a helical bristle structure.

The invention further relates to an air guiding device which is designed as a volume, in particular a duct or the like. It is characterized by a throttle device according to the previous statements.

The air guiding device can preferably be designed as a tube or the like, which has the throttle device on its inner wall. In this way it is possible e.g. B. to accommodate a brush assembly in the tube, which serves as a throttle element or to increase the pressure loss for pressure compensation in a duct system or the like is used.

Spiral-folded pipes are very often used in ventilation technology. These are spirally wound from flat tape and folded at the edges, so that an airtight or essentially airtight connection takes place. According to a preferred exemplary embodiment of the invention, the air guiding device can be designed as a rigid or flexible folded spiral tube, the throttle device preferably being fastened in the fold within the spiral folded tube, preferably the bristles or the like fastened, in particular clamped, with their one ends in the fold. Depending on the desired pressure loss coefficient, the throttle device can extend at least over a partial length of the air guiding device and / or have a correspondingly selected web length of the web arrangement forming the throttle device. The longer the bristles are, the bigger is the flow resistance; the longer the throttle device extends along the direction of flow in the air guiding device, the greater the pressure loss. Fastening the web arrangement, which is preferably in the form of bristles, in the fold of folded spiral-seam tubes leads to the formation of a brush on a helix inside the air guiding device. Additional means for fastening the throttle device then need not be provided. However, it is also possible to attach the throttle device (bristles or a brush or several brushes) separately to the inner jacket of the tube or the like, that is, not to incorporate them into the fold.

The air guiding device can preferably be arranged upstream of an air outlet, in particular a slot outlet. This means that it is upstream of the air outlet. Slot outlets in particular have only a very low pressure drop. In order to precisely adjust the amount of air, for example in the case of adjacent outlets, it may be necessary to increase the outlet loss. So far, a "fixed resistance" has been installed upstream of the air outlets for this purpose, which is designed as a piece of pipe with a perforated plate. According to the invention, instead of this perforated plate, the throttle device can now be used, which, among other things, has optimal acoustic properties, in particular if it is arranged, as described, at a distance upstream of the outlet.

Further advantageous configurations result from the subclaims.

Figur 1

eine Drosselvorrichtung gemäß einem ersten Ausführungsbeispiel,

Figur 2

eine Drosselvorrichtung nach einem weiteren Ausführungsbeispiel,

Figur 3

eine Drosselvorrichtung in einem eckigen Luftkanal,

Figur 4

die Drosselvorrichtung der Fig. 3 in Seitenansicht,

Figur 5

eine weitere Ausführungsform einer Drosselvorrichtung in einem eckigen Luftkanal,

Figur 6

eine Drosselvorrichtung in einem Luftkanal mit kreisförmigem Querschnitt,

Figur 7

die Drosselvorrichtung der Figur 6 in Seitenansicht,

Figur 8

ein weiteres Ausführungsbeispiel einer Drosselvorrichtung in einem Luftkanal mit kreisförmigem Querschnitt,

Figur 9

die Darstellung der Figur 8 in Seitenansicht,

Figur 10

ein Ausführungsbeispiel mit schneckenförmig gestalteter Drosselvorrichtung,

Figur 11

eine verstellbare Drosselvorrichtung in Offenstellung,

Figur 12

die Drosselvorrichtung der Figur 11 in geschlossener Stellung,

Figur 13

eine Draufsicht auf die Drosselvorrichtung der Figur 12,

Figur 14

ein weiteres Ausführungsbeispiel einer Drosselvorrichtung in Offenstellung,

Figur 15

die Drosselvorrichtung der Figur 14 in Schließstellung,

Figur 16

eine Draufsicht auf die geschlossene Drosselvorrichtung der Figur 15,

Figur 17

ein weiteres Ausführungsbeispiel einer kegelförmigen Drosselvorrichtung in Offenstellung,

Figur 18

das Ausführungsbeispiel der Figur 17 in geschlossener Stellung,

Figur 19

ein Diagramm,

Figur 20

eine Drosselvorrichtung mit Kombi-Drosselkörper in Offenstellung,

Figur 21

das Ausführungsbeispiel der Figur 20 in Zwischenstellung,

Figur 22

die Drosselvorrichtung der Figur 20 in Schließstellung,

Figur 23 bis 25

mit Drosselvorrichtungen versehene Auslaßschienen,

Figur 26

einen Drallauslaß mit schneckenförmiger Drosselvorrichtung,

Figur 27

ein Ausführungsbeispiel eines weiteren Drallauslasses,

Figur 28

eine mit Stegen versehende Steganordnung, die den Drosselkörper einer Drosselvorrichtung bildet,

Figur 29

ein Drosselkörper nach einem anderen Ausführungsbeispiel,

Figur 30

ein weiterer Drosselkörper nach einem weiteren Ausführungsbeispiel,

Figur 31

ein winkelförmiger Drosselkörper, der Stege aufweist,

Figur 32

ein Luftauslaß, insbesondere Quelluftauslaß, mit erfindungsgemäßer Drosselvorrichtung,

Figur 33

drei Ansichten eines Luftauslasses, insbesondere Quelluftauslasses, mit erfindungsgemäßer Drosselvorrichtung,

Figur 34

eine Seitenansicht auf eine Luftführungseinrichtung mit im Innern liegender Drosselvorrichtung,

Figur 35

einen Querschnitt durch die Vorrichtung gemäß Figur,

Figur 36

eine schematische Detailansicht der Wandung der Luftführungseinrichtung gemäß Figur 34,

Figur 37

eine Darstellung gemäß Figur 36, jedoch nach einem anderen Ausführungsbeispiel,

Figur 38

einen an eine Luftführungseinrichtung angeschlossenen Schlitzauslaß,

Figur 39,4O

als Flexschlauch ausgebildete Luftführungseinrichtungen,

Figur 41

eine Befestigung einer Drosselvorrichtung am Falz eines Flexschlauches und

Figur 42

eine Anordnung gemäß Figur 41, jedoch nach einem anderen Ausführungsbeispiel.

The drawing illustrates the invention using several exemplary embodiments, namely:

Figure 1

a throttle device according to a first embodiment,

Figure 2

a throttle device according to a further embodiment,

Figure 3

a throttle device in an angular air duct,

Figure 4

3 in side view,

Figure 5

another embodiment of a throttle device in an angular air duct,

Figure 6

a throttle device in an air duct with a circular cross section,

Figure 7

6 the side view of the throttle device,

Figure 8

another embodiment of a throttle device in an air duct with a circular cross-section,

Figure 9

8 shows a side view of FIG. 8,

Figure 10

an embodiment with a helical throttle device,

Figure 11

an adjustable throttle device in the open position,

Figure 12

the throttle device of Figure 11 in the closed position,

Figure 13

12 shows a plan view of the throttle device of FIG. 12,

Figure 14

another embodiment of a throttle device in the open position,

Figure 15

the throttle device of Figure 14 in the closed position,

Figure 16

15 shows a plan view of the closed throttle device of FIG. 15,

Figure 17

another embodiment of a conical throttle device in the open position,

Figure 18

the embodiment of Figure 17 in the closed position,

Figure 19

a diagram

Figure 20

a throttle device with a combined throttle body in the open position,

Figure 21

the embodiment of Figure 20 in the intermediate position,

Figure 22

the throttle device of Figure 20 in the closed position,

Figure 23 to 25

outlet rails provided with throttling devices,

Figure 26

a swirl outlet with helical throttle device,

Figure 27

an embodiment of a further swirl outlet,

Figure 28

a web arrangement provided with webs, which forms the throttle body of a throttle device,

Figure 29

a throttle body according to another embodiment,

Figure 30

another throttle body according to a further embodiment,

Figure 31

an angular throttle body which has webs,

Figure 32

an air outlet, in particular a source air outlet, with a throttle device according to the invention,

Figure 33

three views of an air outlet, in particular a source air outlet, with a throttle device according to the invention,

Figure 34

2 shows a side view of an air guiding device with an internal throttle device,

Figure 35

3 shows a cross section through the device according to FIG.

Figure 36

4 shows a schematic detailed view of the wall of the air guiding device according to FIG. 34,

Figure 37

a representation according to Figure 36, but according to another embodiment,

Figure 38

a slot outlet connected to an air guiding device,

Figure 39.4O

Air guidance devices designed as flexible hoses,

Figure 41

an attachment of a throttle device on the fold of a flexible hose and

Figure 42

an arrangement according to Figure 41, but according to another embodiment.

FIGS. 1-33 show various exemplary embodiments of throttle devices 1 and throttle bodies 2 of throttle devices 1 for setting a gas, in particular air volume flow. Depending on the design, the pressure loss coefficient D desired for the respective application can be achieved by a web arrangement 30. Instead of bristles, webs or bristles can also be used instead of webs.

FIG. 1 shows a throttle body 2, which is guided by an air guide device, not shown, for. B. an air duct is surrounded, and is acted upon by supply air (arrow 3). The throttle body 2 has a rod-shaped holding element 4, on which bristles 5 are arranged in rows next to one another, which form a web arrangement 30. Several adjacent bristles 5 are combined to form bristle tufts 6, so that a row of bristle tufts 7 is formed along the longitudinal extent of the holding element 4.

The rod-shaped holding element 4 extends transversely, in particular perpendicularly to the direction of flow (arrow 3) of the supply air. Alternatively, however, it is also possible for the longitudinal extent of the holding element 4 and the direction of flow (arrow 3) of the supply air to form an angle which deviates from 90 °.

In particular, it is advantageous if the bristles 5 are flowed against transversely to their longitudinal extent by the volume flow to be throttled (arrow 3). According to FIG. 1, it is provided that the direction of the volume flow (arrow 3) with the longitudinal extension of the bristles 5 enclose an acute angle β, that is to say that the supply air - viewed in the direction of the flow - initially hits the holding element 4 End regions of the bristles 5 and only then strokes the free ends 8 of the bristles 5 that are not clamped.

In the exemplary embodiment described in FIG. 1 and also in the exemplary embodiments which follow, it is provided that the bristles preferably consist of plastic or metal wire. In particular, polyethylene, brass or stainless steel are considered as materials.

While the throttle body of FIG. 1 forms a flat element, the shape of which is comparable to that of a comb-like throttle brush 9, spatial elements, for. B. rotationally symmetrical elements, conceivable. In the exemplary embodiment in FIG. 2, the throttle body 2 is a rotationally symmetrical element which has a conical shape. The bristles 5 of this throttle body 2 can either only form a conical area; however, it is also possible that - depending on the desired pressure loss coefficient D - the wall thickness is increased. This can go all the way to a full cone. The individual bristles 5 are fastened in the region of the cone tip 10 by means of a holding element, not shown, so that the bristles are clamped at one end and free at the other end. The inflow with the air flow to be throttled takes place - according to arrow 3 - on the cone tip 10.

FIG. 3 shows a throttle body 2 which is in an air guiding device designed as a rectangular duct is arranged. The throttle body 2 provided with a web arrangement (30) consists of a rod-shaped holding element 4, which is provided on both sides with bristles 5, which - according to FIG. 4 - enclose an angle Winkel which is <than 180 °. There is therefore a type of double-chamber throttle brush 12. The rod-shaped holding element 4 extends parallel to the upper or lower wall 13 of the rectangular channel 11; the bristles 5 run essentially parallel to the side walls 14 of the rectangular channel 11. The inflow in the embodiment of FIGS. 3 and 4 with supply air or the like takes place in such a way that - according to arrow 3 - the volume flow first onto the clamped end regions of the bristles 5 and then onto hits the further downstream free ends 8 of the bristles 5. The free ends 8 preferably extend to the upper or lower wall 13 of the rectangular channel. However, a distance can also remain there, provided this is necessary to achieve the desired pressure loss coefficient D. The inclination of the bristles 5 to the direction of flow (arrow 3) is also selected as a function of the desired pressure loss coefficient D.

According to the embodiment of Figure 5, it is also possible to hold the holding element 4 in the region of a wall, for. B. to arrange top wall 13 of the rectangular channel. The bristles 5 then extend over the entire height of the rectangular channel 11.

In the exemplary embodiments already described and also in the following exemplary embodiments it is possible that the throttle devices 1 are formed in one or more stages. Multi-stage means that a plurality of bristles 5 or rows of bristles and / or tufts of bristles - as seen in the direction of flow - are arranged one behind the other. For example, several throttle bodies 2 can be passed one behind the other by the volume flow to be throttled.

The exemplary embodiment in FIG. 6 shows a throttle device 1 which, as an air guiding device, has a channel 15 with a circular cross section. The throttle body 2 is designed in accordance with the throttle body 2 of the exemplary embodiment in FIG. 3. There is, however, the difference that the bristles 5 of the web arrangement 30 do not all have the same length, but rather — to the sides — have a shorter length corresponding to the cross-sectional contour of the air guiding device.

FIG. 7 shows a side view of the arrangement according to FIG. 6. Here too, the rows of bristles form an angle Θ on both sides of the holding element, which is <than 180 °.

FIG. 8 shows an exemplary embodiment with an air guiding device which is circular in cross section and a throttle body 2 designed as a cone. The cone tip 10 is located in the center of the channel 15.

In the exemplary embodiment in FIG. 10, a throttle body 2 is provided, in which the bristles 5 of the web arrangement 30 are arranged in a helical manner, i. that is, there is a bristle screw 16. Depending on the angular position (slope) of the bristles 5 and the number of turns of the bristle screw 16, the desired pressure loss coefficient D is set.

In the previous exemplary embodiments of FIGS. 1-10, there is a "fixed" pressure loss coefficient D. In the following exemplary embodiments of FIGS. 11-22, the pressure loss coefficient D can be adjusted, in which the throttle body 2 is adjustable, so that - depending on the position - one corresponding pressure loss coefficient can be brought about. In ventilation technology z. B. controls or regulations of air volume flows possible.

In the exemplary embodiment in FIG. 11, there is an air guiding device with a rectangular cross section (rectangular duct 11). The arrangement corresponds to the exemplary embodiment in FIG. 5. However, the difference is that the holding element 4 is rotatably mounted (arrow 17), so that the bristles 5 of the throttle body 2 can be pivoted. Depending on the angular position of the bristles, the associated pressure loss coefficient D is set. An open position of the throttle body 2 is shown in FIG. The closed position is shown in FIG. The bristles 5 have a length that is greater than the distance between the upper and lower wall 13 of the Rectangular channel 11 is, so that in the closed position there is a deflection. Because of this deflection, the bristles 5 bundle, as a result of which the pressure loss coefficient D increases. In the case of the plastic bristle in particular, it is ensured that it springs back into its old shape / position again and again. This is also the case with spring wire.

FIG. 13 shows the top view of the exemplary embodiment in FIG. 12.

Figures 14 to 16 show an embodiment which corresponds to the embodiment of Figures 3 and 4. However, there is an angle Θ between the rows of bristles that is not <180 °, but 180 °. The individual positions of the throttle body 2 in FIGS. 14-16 correspond to the positions of the throttle body 2 in FIGS. 11-13. In the exemplary embodiment in FIGS. 14-16, there is an air guiding device with a channel cross section that is circular in cross section; the throttle body 2 is double comb-like.

The exemplary embodiment in FIG. 17 shows a conical throttle body 2 which can be displaced longitudinally in or against the direction of flow (arrow 3) by suitable means, not shown, within the air guiding device 18. Depending on the position of the throttle body 2, a throttle cross section 19 of the air guiding device 18 can be more or less closed due to the conical shape of the throttle body 2, whereby the desired pressure loss coefficient D can be set.

As mentioned, when the throttle devices 1 according to the invention are closed, it can be provided that the bristles 5 of the respective throttle body 2 bundle, as a result of which the pressure loss coefficient D increases. However, the pressure loss coefficient D does not increase as much as it does e.g. B. for flaps with airtight damper blade. If one looks at the diagram in FIG. 19, then the curve 20 shows the relationship between the pressure loss coefficient D as a function of the angular position α of the throttle body 2. It is assumed that the closed position is reached at α = 90 °. Curve 20, which has a relatively strong curvature, shows the relationship between D and α in conventional flaps with an air-impermeable flap leaf. With 21 a curve is designated which corresponds to a throttle body 2 according to the invention with bristles 5. It becomes clear that the large values of the pressure loss coefficient D cannot be achieved as with the air-impermeable conventional valve. However, there is an approximately linear relationship between D and α. This more linear relationship between the pressure loss coefficient D and the angle of rotation α benefits control devices, which can work more stable and more accurate.

The curve 22 (dashed line) in FIG. 19 shows the dependence of the pressure loss coefficient D on the angle of rotation α of a throttle device 1 according to 20 to 22. The throttle body 2 is designed as a combination flap 23, ie a part provided with bristles 5 and a conventional, air-impermeable flap leaf 24 are provided. The bristles 5 and the flap leaf 24 make an angle δ between them. The arrangement is such that when the throttle body 2 is closed, the bristles 5 initially - according to FIG. 21 - step against the air guiding device, as a result of which the pressure loss coefficient D increases in accordance with curve 22. This takes place approximately up to the end point of curve 21. In the course of further closing, the damper blade 24 then — essentially with the elimination of the angle δ — against the wall of the air guiding device, as a result of which the pressure loss coefficient D increases still further and finally reaches an end value (curve 22), which corresponds to the end value of curve 20.

FIGS. 23-25 show air outlets 26 provided with outlet rails 25. Each outlet rail 25 has an air guide roller 26. In the feed to the outlet rail 25, a throttle device 1 with a web arrangement 30 is arranged, the design of which corresponds to the design according to the invention with bristles 5. In the exemplary embodiments in FIGS. 23-25, the throttle body 2 is arranged directly upstream of the respective outlet rail 25. This improves the flow against the air guide roller 26 and the distribution over the outlet length. In addition to the desired pressure loss, the throttle bodies enable 2 a reduction in the number of connecting pieces for the supply of the supply air, which saves assembly costs and material costs. Due to the design of the throttle body 2 according to the invention, the throttling noises are very strongly damped, so that the noises do not "shine through", which is often the case with conventional air outlets, in particular air outlets with an outlet rail.

FIG. 26 shows a low-noise swirl generator 27. This can be installed in a very compact housing and can also be flowed at in a non-uniform manner. Due to the design of the throttle body 2 according to the invention, this is nevertheless without adverse effects on the flow noise. The throttle valve 2 is helical.

The exemplary embodiment in FIG. 27 shows a swirl generator 27 which has air guide vanes 28 which are designed in the form of circular sections. According to the invention, they have bristles 5 which, for example, can be clamped at one end in corresponding holding elements 4. The arrangement of the air guide vanes 28 is provided in the manner of a propeller. Due to the inventive design of the throttle valve 2 forming air guide vanes 28 pronounced separation areas are prevented by incorrect flow, so that extremely quiet operation is possible.

The brush-shaped throttle body 2 according to the invention combine the advantages of a low-noise Throttling with low maintenance or freedom from maintenance and low manufacturing costs.

FIGS. 28 to 31 show exemplary embodiments of throttle bodies 2 which have webs 31 which form the web arrangement 30 instead of the bristles of the previous exemplary embodiments. These embodiments of the throttle body 2 can be used in throttle devices 1 according to the embodiments shown in the course of this application instead of the bristles provided there.

According to the exemplary embodiment in FIG. 28, webs 31 are provided which have the same lengths and the same widths and also the same gap widths between them. The webs 31 are preferably designed as sheet metal webs. In turn, brass or a stainless steel is preferably used as the material. However, it is also possible for the throttle bodies 2 provided with webs 31 to be made of plastic, preferably of polyethylene.

In the embodiment of Figure 29, the webs 31 have different shapes. The lengths of the webs 31 are different and also their widths. Furthermore, the gaps between adjacent webs 31 are of different sizes. Preferably, as shown, the individual webs 31 can also have an irregular shape, that is to say, for example, they are pointed to or are provided with curvatures and the like.

In the exemplary embodiments in FIGS. 28 and 29, the webs 31 are preferably formed in one piece with a holding element 4 (transverse web). In particular, the throttle bodies 2 of the exemplary embodiments in FIGS. 28 and 29 form throttle brushes which have a comb-like shape.

In the exemplary embodiment in FIG. 30, two throttle bodies 2 provided with webs 31 are arranged one behind the other, so that a multi-stage throttle device is formed. Both throttle brushes 9 together form the web arrangement 30.

According to the exemplary embodiment in FIG. 31, angular throttle bodies 2 can also be formed, that is to say two comb-like throttle bodies provided with webs 31 preferably hang together in one piece on their lower edge of the holding element 4 and are bent there at an angle to one another. This configuration corresponds to the configuration according to FIG. 7, however, webs 31 are provided instead of the bristles shown there. In the exemplary embodiment in FIG. 31, for example, a sheet metal strip can be provided with the webs 31 by punching and then bent accordingly by folding.

FIG. 32 shows a source air outlet 35 which is designed as a linear outlet element. The supply air (arrow 3) enters air inlet connection 36 a, which open into an air distribution box 37. The air distribution box 37 has a slot 38. On one slot boundary wall, bristles 5 of a throttle body 2 are arranged, which at least partially cover the slot and throttle the air escaping there. The free ends of the bristles 5 face an angled sheet metal wall 39 of the other slot boundary wall. The rear wall 40 of the air distribution box 37 extends beyond the plane of the slot 38. At its upper end there is a cover 42 which is provided with air outlet openings 41 and which curves in a quarter circle over the slot 38 and extends to the upper wall of the air distribution box 37. The arrows drawn there represent the air outlet. The air outlet openings 41 are of such a size that they expose more than 40% of the cover area. Because of the bristles 5, an excellent air distribution along the outlet is achieved.

In the exemplary embodiment in FIG. 33, a further displacement air outlet 35 is shown in three different views. It has a cuboidal air distribution box 37, into which an air inlet nozzle 36 opens. The air distribution box 37 is provided with a plurality of slots 38 running parallel to one another, a sheet metal wall 39 preferably being angled vertically from one slot side. Bristles 5 extend from the other slot side and partially or completely cover the respective slot 38, so that the throttle body 2 is formed there. According to the illustration on the left of FIG. 33, a cover 42 can also be provided, as in the exemplary embodiment in FIG. 32, which covers the slots 38 and which is provided with air outlet openings 41 which expose an outlet surface> 40% of the cover surface. The row of brushes (bristles 5) are very easily accessible after removing the cover 42. Because of the bristles, a good, even speed distribution of the outflowing air is achieved. Furthermore, the construction of the exemplary embodiment in FIG. 33 enables the displacement air outlet 35 to have a very low overall height.

FIG. 34 shows an air guiding device 50, which is designed as a tube 51 and carries a throttle device 1 inside (FIG. 35). The tube 51 is a rigid spiral-seam tube 51 ', which is wound spirally from flat strip, the edges 52 being folded and thereby connected to one another. Such folds 53 can be seen in FIGS. 36 and 37. According to FIGS. 36 and 37, open or closed beads 54 can be formed between the folds 53.

FIG. 35 shows a cross section through the folded spiral tube 51 'according to FIG. 34. It can be seen that the throttle device 1 is designed as bristles 5, which are fixed at one end to the inner side of the folded spiral tube 51' and project approximately radially inwards. The bristles 5 are preferably fastened in the fold 53, as can be seen from FIGS. 36 and 37. This results in a helical brush inside the tube 51 is formed. The bristles 5 are preferably jammed in the fold 53. The length of the bristles and the formation of the brush thus formed over the length of the tube is selected depending on the desired pressure loss coefficient.

Alternatively, it is also possible according to an embodiment not shown, not to incorporate the bristles into the fold, but to fasten them separately on the inner tube surface with suitable means.

According to FIG. 38, an air guiding device 50 designed with a throttle device 1 can be connected to a connecting piece 55 of an air outlet 56. The air outlet 56 is preferably a slot outlet. The air guiding device 55 is designed as a flexible tube, in particular as a flexible hose 57. Instead of this, for example, a rigid spiral duct can also be used. It is essential that a throttle device 1 is connected upstream of this connection to the air outlet 56 to increase the pressure loss in order to, for. B. to achieve a desired pressure balance.

Figures 39 and 40 illustrate that the air guide device 50 can be installed in the desired manner, even with strong curvatures, when it is designed as a flexible hose 57. Figures 41 and 42 show longitudinal sections through the wall of flexible hoses, which are spirally wound from band sections and folded at the edges 52 (folds 53). Bristles 5 of a throttle device 1 are clamped in the folds 53.

The exemplary embodiment in FIG. 41 is a fold 53 which is realized on an inner layer 58 of the flexible hose 57. In the exemplary embodiment in FIG. 42, the inner layers 58 and outer layers 59 of the flexible hose 57 are alternately connected to one another by folds. The corresponding ends of the bristles or webs or the like are clamped into the fold pocket formed in each case. It is of course also possible to glue the bristles additionally or exclusively in the folding pocket.

Claims (33)

Air-technical throttle device for setting a gas, in particular air volume flow, with a throttle body, characterized in that the throttle body (2) has a web arrangement (30) effecting the throttling. Throttle device according to claim 1, characterized in that the webs (31) of the web arrangement (30) are formed by bristles (5). Throttle device according to claim 1, characterized in that the webs (31) of the web arrangement (30) are formed by plastic or sheet metal webs. Throttle device according to one of the preceding claims, characterized in that the webs (31) of the web arrangement (30) or the bristles (5) are arranged in rows next to one another. Throttle device according to one of the preceding claims, characterized in that a plurality of adjacent webs (31) or bristles (5) each form a web tuft (32) or bristle tuft (6). Throttle device according to one of the preceding claims, characterized in that a plurality of web tufts (32) or bristle tufts (6) are arranged side by side to form a row of web tufts (33) or bristle tufts (7). Throttle device according to one of the preceding claims, characterized in that, seen in the direction of flow, a plurality of webs (31) or bristles (5) lie one behind the other. Throttle device according to one of the preceding claims, characterized in that the webs (31) or bristles (5) are held at one end in a holding element (4) and in that the respective other end of the webs (31) or bristles (5) is a free one End (8) forms. Throttle device according to one of the preceding claims, characterized in that the webs (31) or bristles (5) are flowed against by the volume flow to be throttled transversely to their longitudinal extent. Throttle device according to one of the preceding claims, characterized in that the direction of the volume flow forms an angle with the longitudinal extension of the webs (31) or bristles (5). Throttle device according to one of the preceding claims, characterized in that the direction of the downstream volume flow with the from the held end of the webs (31) or bristles extending to the free end of the longitudinal extension of the webs (31) or bristles (5) encloses an acute angle (β). Throttle device according to one of the preceding claims, characterized in that the webs (31) or bristles (5) are held at one end in a clamping device (holding element 4), in particular a clamping strip. Throttling device according to one of the preceding claims, characterized in that the throttling bristles - depending on the desired pressure loss coefficient (D) - are arranged one after the other or in several stages in the direction of flow. Throttle device according to one of the preceding claims, characterized in that the bristles (55) are arranged to be adjustable, in particular pivotable, for the optional setting of the pressure loss coefficient (D). Throttle device according to one of the preceding claims, characterized in that the holding element (4) can be displaced in order to adjust the bristles (5). Throttle device according to one of the preceding claims, characterized in that the free end regions of adjustable, in particular pivotable, bristles (5) in the end region of such adjustment step against an air flow limiting wall (wall of an air guiding device), that they compress, in particular that the bristles (5) bend. Throttle device according to one of the preceding claims, characterized in that the bristles (5) consist of plastic or metal wires. Throttle device according to one of the preceding claims, characterized in that the webs (31) or bristles (5) consist of plastic, brass or stainless steel. Throttle device according to one of the preceding claims, characterized in that the webs (31) or bristles (5) have a circular cross section. Throttle device according to one of the preceding claims, characterized in that the webs (31) or bristles (5) form a throttle brush (12). Throttle device according to one of the preceding claims, characterized in that the throttle brush (12) is designed like a comb. Throttle device according to one of the preceding claims, characterized in that the webs (31) or bristles (5) form a conical throttle element (2), the cone tip (10) of which the flow flows. Throttle device according to one of the preceding claims, characterized in that the throttle brush (12) is designed in the manner of a double comb due to two rows of bridges or rows of bristles, preferably both rows of bridges or rows of bristles enclosing a downstream angle (Θ) which is <180 °. Throttle device according to one of the preceding claims, characterized in that the webs (31) or bristles (5) form a bristle screw (16). Throttle device according to one of the preceding claims, characterized in that the webs (31) are formed in one piece with the holding element (4). Throttle device according to one of the preceding claims, characterized in that the webs (31) or bristles (5) have different shapes, in particular different web widths and / or lengths or bristle thicknesses and / or lengths. Throttle device according to one of the preceding claims, characterized in that the gaps between adjacent webs (31) or bristles (5) are of different widths. Air guiding device which is designed as a volume, in particular a duct or the like, characterized by a throttle device according to one or more of the preceding claims. Air guiding device according to claim 28, characterized in that it is designed as a tube (51) or the like which has the throttle device (1) on its inner wall. Air guiding device according to one of the preceding claims, characterized by the design as a rigid or flexible folded spiral tube (51 '), the throttle device (1) preferably being fastened in the fold, in particular the bristles being fastened with one end to the fold, preferably being clamped . Air guiding device according to one of the preceding claims, characterized in that the throttle device (1) - depending on the desired pressure loss coefficient - extends over at least a partial length of the air guiding device (50) and / or has a corresponding web length of the web arrangement (30). Air guiding device according to one of the preceding claims, characterized in that it is designed as a flexible tube, in particular a flexible hose (57). Air guiding device according to one of the preceding claims, characterized in that it is arranged upstream of an air outlet (56), in particular a slot outlet.

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