EP3385630A1 - Fluid guiding device and ventilation device therewith - Google Patents

Abstract

The invention relates to a fluid deflection device (1) having an inner wall (3), an intermediate wall (4) and an outer wall (5) which are each circular cylindrical with respect to a longitudinal central axis (26) of the fluid deflection device (1), wherein on a first axial side the fluid deflection device (1) on a first radial side of the intermediate wall (4), in particular between the inner wall (3) and the intermediate wall (4), a first inner fluid port (16) and on a second radial side of the intermediate wall (4), in particular between the intermediate wall (4) and the outer wall (5), a first outer fluid connection (17) and on a first axial side opposite second axial side of the fluid deflection means (1) on the first radial side of the intermediate wall (4), in particular between the Inner wall (3) and the intermediate wall (4), a second inner fluid port (18) and on the second radial side of the intermediate wall (4), in particular between the Z a second outer fluid port (19), wherein the first inner fluid port (16) is in fluid communication with the second outer fluid port (19) and fluidly from the second inner fluid port (18) and the first outer fluid port (17) is in fluid communication with the second inner fluid port (18) and is fluidly isolated from the second outer fluid port (19). The invention further relates to a ventilation device (2).

Description

The invention relates to a fluid deflection device, which is present for example as part of a ventilation device.

The fluid deflection device serves in particular for a distribution and / or a deflection of a fluid. The fluid is in the form of air, for example, so that the fluid deflection device can also be referred to as an air deflection device. The fluid deflection device is particularly preferably a component of the ventilation device, which is configured, for example, as a ventilation device or ventilation system, in particular as a facade ventilation device. The facade ventilation unit is designed to be integrated into a wall of a building. In addition to the fluid deflection device, the ventilation device preferably has at least one heat exchanger and / or an air conveying device, for example a fan or the like.

It is an object of the invention to provide a fluid deflection device which has advantages over known fluid deflection devices, in particular has low flow losses and at the same time is easy and inexpensive to produce.

This is achieved according to the invention with a fluid deflection device having the features of claim 1. It is provided that the fluid deflection means comprises an inner wall, an intermediate wall and an outer wall which are each circular cylindrical with respect to a longitudinal central axis of the fluid deflection means, wherein on a first axial side of the fluid deflection means on a first radial side of the intermediate wall, in particular between the inner wall and the intermediate wall a first inner fluid port and on a second radial side of the intermediate wall, in particular between the intermediate wall and the outer wall, a first outer fluid port and on a first axial side opposite the second axial side of the fluid deflection means on the first radial side of the intermediate wall, in particular between the Inner wall and the intermediate wall, a second inner fluid port and on the second radial side of the intermediate wall, in particular between the intermediate wall and the outer wall, a second outer fluid port is formed , in which the first inner fluid port is in fluid communication with the second outer fluid port and fluidly isolated from the second inner fluid port, and the first outer fluid port is in fluid communication with the second inner fluid port and fluidly isolated from the second outer fluid port.

Overall, the fluid deflection device or at least the said walls, so the inner wall, the intermediate wall and the outer wall, constructed a circular cylindrical, namely with respect to the longitudinal center axis. The longitudinal central axis of the fluid deflection device corresponds to the longitudinal central axis of the circular cylindrical inner wall, the longitudinal central axis of the circular cylindrical intermediate wall and the longitudinal central axis of the circular cylindrical outer wall, which coincide insofar.

Said fluid connections, that is to say the first inner fluid connection, the first outer fluid connection, the second inner fluid connection and the second outer fluid connection are arranged in pairs on opposite axial sides of the fluid deflection device, ie on opposite end faces of the fluid deflection device. In this case, the two first fluid connections, that is to say the first inner fluid connection and the first outer fluid connection, are arranged or formed on the same side of the fluid deflection device. The same applies to the two second fluid connections, that is to say the second inner fluid connection and the second outer fluid connection.

The fluid connections are each circular or annular. Thus, the inner fluid connections are limited in the radial direction to the outside of the intermediate wall and can be continuous in the radial direction inwardly to the longitudinal central axis. In that regard, the corresponding inner fluid port is circular. Alternatively, it may of course be provided that the inner fluid connection is limited in the radial outward direction of the intermediate wall and in the radial direction inwardly of the inner wall, so that it is annular. At least one of the outer fluid ports is bounded radially inwardly by the intermediate wall and radially outward by the outer wall so that it is annular. This is particularly preferred for both outer fluid connections. The intermediate wall serves on both sides of the fluid deflection device in each case the fluidic separation of the corresponding inner fluid port from the outer fluid port on the same axial side. Preferably, it is therefore provided that the intermediate wall and the outer wall have mutually aligned end faces, which are so far on the same plane perpendicular to the longitudinal center axis plane.

Seen in longitudinal section, that is cut along the longitudinal central axis, the first fluid connections to the second fluid ports are cross-connected in flow communication. Thus, the first inner fluid port should be fluidly connected to the second outer fluid port, but be fluidly separated from the second inner fluid port. At the same time, the first outer fluid port is to be in fluid communication with the second inner fluid port and fluidly separated from the second outer fluid port. In the interior of the fluid deflection device, the fluid entering through one of the fluid ports always experiences a deflection in the radial direction, namely in the radial direction inwards or in the radial outward direction, before it exits the fluid deflection device on the axially opposite side. Such a configuration of the fluid deflection device enables a compact design of the ventilation device. Due to the construction of the fluid deflection device with the three walls, namely the inner wall, the intermediate wall and the outer wall, which are preferably also arranged coaxially or concentrically to each other, also a simple manufacturability is given at the same time high dimensional stability of the fluid deflection device.

A further embodiment of the invention provides that the fluid connection exists between the first inner fluid port and the second outer fluid port via at least one first flow chamber and the fluid connection between the first outer fluid port and the second inner fluid port via at least one second flow chamber. The fluid connections are by definition preferably in the respective front side plane of the fluid deflection device. Preferably, the first fluid ports lie completely in a first plane and the second fluid ports lie completely in a second plane parallel thereto, the planes being spaced apart in the axial direction. Preferably, the two planes are each perpendicular to the longitudinal central axis. The two planes can each receive opposite end faces or end faces of the outer wall and / or the intermediate wall and / or inner wall.

Each of the fluid connections, on the one hand the fluid connection between the first inner fluid port and the second outer fluid port and the other fluid connection between the first outer fluid port and the second inner fluid port, each associated with a flow chamber, wherein the flow chambers as the first flow chamber and the second flow chamber will be referred to. Of course, in each case a plurality of fluid connections can be provided, so that several first flow chambers and / or a plurality of second flow chambers can be realized. Particularly preferably, the fluid deflection device has the same number of first flow chambers and second flow chambers.

The first inner fluid port can be connected to the first flow chamber via a first inner flow channel, whereas it is connected to the second outer fluid port via a second outer flow channel. Analogously thereto, it may be provided that the first outer fluid port is in fluid communication with the second inner fluid port via a first outer flow passage and the latter in turn via a second inner flow passage with the second inner fluid port. Preferably, a plurality of first flow chambers and a plurality of second flow chambers are formed.

The flow channels are preferably straight in each case and each have a longitudinal central axis which runs parallel to the longitudinal central axis. Alternatively, the first flow chamber may be bounded on the one hand by the first inner fluid port and on the other hand by the second outer fluid port. In this case, the second flow chamber is bounded on the one hand by the first outer fluid port and on the other hand by the second inner fluid port. In other words, the first flow chamber closes on the one hand directly to the first inner fluid port and on the other hand directly to the second outer fluid port. Accordingly, the second flow chamber closes on the one hand directly to the first outer fluid port and on the other hand directly to the second inner fluid port.

The flow chambers, that is to say the first flow chamber and the second flow chamber, are preferably configured in each case for deflecting the fluid flow. Thus, preferably in the first flow chamber, a deflection takes place radially from the first inner fluid connection in the outward direction to the second outer fluid connection and in the second flow chamber a deflection in the radial direction inwards starting from the first outer fluid connection towards the second inner fluid connection or respectively vice versa. Preferably, the flow chambers are configured such that the fluid flowing into them through one of the fluid connections flows in parallel to the longitudinal central axis and is deflected there in the radial direction before it exits the fluid deflection device through another of the fluid connections.

A preferred further embodiment of the invention provides that the first flow chamber and / or the second flow chamber each seen in the radial direction in a first flow area inside of the inner wall and / or outside of the intermediate wall, and / or in a second flow area inside of the Inner wall and outside of the outer wall, and / or in a third flow area is bounded on the inside of the inner wall and on the outside of the outer wall. At least one of the flow chambers, but preferably both flow chambers, are subdivided into the different flow regions. In the first flow region, it may be provided-viewed in longitudinal section with respect to the longitudinal central axis-that the respective flow chamber is bounded only in the radial outward direction by the intermediate wall, while it is continuous in the radial direction, that is, as far as the longitudinal central axis extends. Alternatively, however, it can be provided that the respective flow chamber - seen in longitudinal section with respect to the longitudinal central axis - is defined in the first flow region in the radial direction inside of the inner wall and the outside of the intermediate wall and insofar extends annularly between them.

In the second flow region, the respective flow chamber extends - viewed in longitudinal section with respect to the longitudinal central axis - in the radial direction from the inside out, starting from the inner wall to the outer wall. On the other hand, in the third flow region, it is bordered on the inside by the intermediate wall and on the outside by the outer wall, viewed in longitudinal section with respect to the longitudinal central axis. It becomes clear that the respective flow chamber has the greatest extent in the radial direction in the second flow region. In the second flow region, the deflection in the radial direction, that is to say starting from the first flow region in the radial direction outwards towards the second flow region or vice versa in the radial direction inwards starting from the third flow region up to the first flow region, also takes place.

A further embodiment of the invention provides that the inner wall, the intermediate wall and the outer wall are connected to one another via radial webs, wherein in each case two of the radial webs bound the first flow chamber and / or the second flow chamber in the circumferential direction. The radial webs preferably extend in a plan view or in cross section, viewed straight in the radial direction from the inside to the outside. For example, they begin on the inner wall and extend to the outer wall. However, it can also be provided that they extend in the radial direction continuously from the longitudinal center axis to the outer wall, preferably continuously straight. Are so far more than two radial webs provided, they are preferably arranged star-shaped relative to each other or with respect to the longitudinal central axis.

In each case two of the radial webs bound the first flow chamber and / or the second flow chamber in the circumferential direction. If only exactly two radial webs are provided, then they are aligned with each other so that one of the radial webs represents the extension of the other of the radial webs. In such an embodiment, the radial webs delimit the first flow chamber on the one hand and the second flow chamber on the other hand delimit the two flow chambers from one another. Preferably, however, more than two radial webs are provided, more preferably, the number of radial webs is a multiple of two. Each of the radial webs bounded so far in the circumferential direction on the one hand, the first flow chamber or one of the first flow chambers and in the circumferential direction on the other hand, the second flow chamber or one of the second flow chambers.

A development of the invention provides that the respective two of the radial webs on their first axial side facing end surfaces via a the inner wall and the intermediate wall interconnecting and spaced from the outer wall inner flow guide wall are interconnected and / or or on their second axial side facing end surfaces via a the intermediate wall and the outer wall interconnecting and spaced from the inner wall outer flow guide wall are interconnected. The radial webs are, as already explained above, at least between the inner wall and the outer wall, formed continuously. For flow-related separation of the first flow chamber from the second flow chamber, the flow guide walls, that is to say the first flow guide wall and the second flow guide wall, are now provided.

The inner flow guide wall extends in the radial direction between the inner wall and the intermediate wall, ie in the radial direction, starting from the inner wall up to the intermediate wall. Likewise, it extends in the circumferential direction, starting from one of the radial webs to the other of the radial webs. In an analogous manner, the outer flow guide wall extends in the radial direction, starting from the intermediate wall to the outer wall and in the circumferential direction, starting from one of the radial webs to the other of the radial webs.

Particularly preferably, two of the radial webs, which are connected to each other via the inner flow guide wall, not connected to each other via an outer flow guide wall and vice versa. One of the radial webs is so far connected to a first further of the radial webs on the inner flow guide wall and with a second further of the radial webs via an outer flow guide wall. In other words, each of the radial webs engages an inner flow guide wall and an outer flow guide wall, which, however, extend in opposite directions in the circumferential direction.

In a further embodiment of the invention it is provided that the inner flow guide wall and / or the outer flow guide wall is curved in the circumferential direction, in particular continuously or only in a region adjacent to the radial webs curvature region, and / or merges tangentially into the radial webs. Due to the curvature of the flow guide wall, an extremely low pressure loss of the fluid deflection device is achieved. The curvature is in the circumferential direction, wherein preferably the inner flow guide wall, in particular in the middle in the circumferential direction, has a greater curvature than the outer flow guide wall. In particular, the curvature may be continuous or may be limited to the curvature region (s) to which the respective flow guide wall merges into the radial web (s). Particularly preferred is an embodiment in which the respective flow guide wall tangentially into at least one of the radial webs, but more preferably in both of the radial webs, merges and for this purpose has a corresponding curvature. The curvature can basically be concave or convex.

A preferred embodiment of the invention provides that the inner flow guide wall and / or the outer flow guide wall are inclined in the radial direction and / or in the tangential direction, in particular are inclined in opposite directions. In addition or as an alternative to the above-described curvature of the respective flow guide wall, this may be inclined. The inclination is provided in the radial direction and / or in the circumferential direction. The inclination in the radial direction is to be understood that the flow guide wall at different radial positions have different axial positions, so for example in the radial direction from the inside outwards in the axial direction to the rear or front or more generally tilted in one or the other direction. The inclination in the tangential direction is provided such that the flow-guiding wall has different axial positions at different tangential positions. The tangential Direction may alternatively be referred to as the circumferential direction and correspondingly the tangential position as a circumferential position. The inclination in the tangential direction is directed, for example, such that a possibly present circumferential component of the flow is converted into an axial component.

A further advantageous embodiment of the invention provides that the outer flow guide wall directly adjoins an end face of the intermediate wall which is located in the axial direction and the inner flow guide wall acts on the end face of the intermediate wall via a connecting web continuing on the intermediate wall. The intermediate wall is preferably not continuously configured in the axial direction, but is divided into two intermediate wall portions, which are spaced apart in the axial direction. The intermediate wall or one of the intermediate wall areas in this respect has an end face lying in the axial direction. From this, the outer flow guide wall is preferably directly out. For the inner flow guide wall this is not true. Rather, this is connected via the connecting web to the end face. The connecting web continues the partition and thus forms an extension in the axial direction of this. Preferably, the connecting web is limited in the circumferential direction on both sides in each case by an outer flow guide wall.

A further particularly preferred embodiment of the invention provides that the fluid deflection device has two axial regions adjoining one another in the axial direction, wherein each of the axial regions has an inner wall region of the inner wall, an intermediate wall region of the intermediate wall, an outer wall region of the outer wall and radial web regions of the radial webs, wherein the outer wall regions, the inner wall areas and the Radialstegbareiche adjacent to each other and the intermediate wall portions are aligned with each other in alignment in the axial direction from each other. On such a configuration has already been noted. The fluid deflection device is so far at least intellectually in two areas, namely the two axial areas, divisible. The two axial regions preferably have the same extension in the axial direction, that is, they have the same axial extension.

The inner wall areas and the outer wall areas directly adjoin one another in the axial direction, so that the inner wall and the outer wall are each in the form of a continuous circular cylinder. Also, the radial web portions of the radial webs are seen in the axial direction directly adjacent to each other, so that in the axial direction continuous axial webs are configured. However, the intermediate wall portions are spaced from each other in the axial direction and are located each as a circular cylinder before. The formation of the intermediate wall or the intermediate wall regions enables a simple fluid separation of the inner fluid connections from the outer fluid connections and to that extent a compact configuration of the fluid deflection device.

A development of the invention provides that in each of the axial regions in the circumferential direction alternately engage an inner flow guide wall and an outer flow guide wall on the respective partition wall region, so that the flow guide walls of the axial regions are arranged in rows spaced apart in the axial direction. At least one inner flow guide wall and one outer flow guide wall are present in each of the axial regions so far, but preferably in each case a plurality of inner flow guide walls and a plurality of outer flow guide walls.

The at least one flow guide wall and the at least one outer flow guide wall of each of the axial regions are seen in the axial direction or in longitudinal section at least partially overlapping each other. However, the flow guide walls of the different axial regions are spaced apart from one another in the axial direction or at most adjoin one another directly in the axial direction. In any case, however, the flow guide walls of one of the axial portions in a first row and the flow guide walls of another of the axial portions in a second row, wherein the two rows are spaced apart in the axial direction.

A preferred further embodiment of the invention provides that each of the axial regions is in each case formed by a fluid distribution element and the fluid distribution elements are present as identical parts. The fluid distribution elements are constructed completely identical to one another and are arranged to one another, in particular to one another, for forming the fluid deflection device. The fastening can basically be done in any manner, for example, a positive and / or a cohesive fastening is provided. The formation of the fluid distribution elements as equal parts enables a cost-effective production of the fluid deflection device, because the fluid distribution elements can be produced by means of the same tool, for example by injection molding or the like.

A further embodiment of the invention provides that the fluid distribution elements are connected to each other angularly offset in the circumferential direction. The two fluid distribution elements are so far not connected to each other in the same angular orientation, but rather, an angular offset is provided around preferably one of the radial webs. The angular offset is selected such that the fluid connection described in the beginning between the first inner fluid port and the second outer fluid port on the one hand and the former fluid port and the second inner fluid port on the other hand is realized.

Within the scope of a preferred embodiment of the invention, it is provided that the first inner fluid port and the second inner fluid port have the same flow cross-section and / or that the first outer fluid port and the second outer fluid port have the same flow cross-section. This is achieved in particular by the coaxial arrangement of the intermediate wall regions. The inner wall and the outer wall are in this case designed to be continuous in the axial direction anyway and circular cylindrical. Of course, in principle, different flow cross-sections can be realized, so that therefore the first inner fluid port and the second inner fluid port and / or the first outer fluid port and the second outer fluid port (each) have mutually different flow cross-sections.

A development of the invention provides that one of the first axial side facing end face of the inner wall offset in the axial direction in the direction of the second axial side and / or arranged a second axial side facing end face of the inner wall in the axial direction in the direction of the first axial side is, in particular in each case for forming a receiving chamber, preferably for a fan device and / or a cross-section adjustment. It has already been explained above that the end faces or end faces of the outer wall and the intermediate wall, viewed in the axial direction, are preferably aligned with one another, in particular on both sides of the fluid deflection device in the axial direction. In contrast to this, the end faces of the inner walls or at least one of the end faces can be offset inward in the axial direction, so that, firstly, in the first flow region the first flow chamber or the second flow chamber is indefinitely in the radial direction, ie extends as far as the longitudinal central axis and on the other hand the arrangement of further facilities is possible.

Preferably, the resetting of the end face of the formation of the receiving chamber for the fan device and / or for the cross-section adjustment is used. The fan device has, for example, an impeller which is arranged in the receiving chamber, whereas a motor of the fan device can be arranged in a chamber bounded radially outwards by the inner wall. Additionally or alternatively to the fan device the cross-section adjustment device can be provided in the receiving chamber, by means of which the flow cross-section of at least one of the flow chambers, preferably both flow chambers, is adjustable. Preferably, the flow cross-section is arbitrarily adjustable by means of the cross-section adjustment, in particular the flow connection optionally completely interruptible or completely releasable. The receiving chamber is preferably adapted in its dimensions to the fan device or the cross-section adjustment, for example, a motor of the fan device is at least partially at its outer peripheral surface on a receiving chamber bounding inner peripheral surface, in particular such that it is fixed non-positively and / or positively in the receiving chamber. Alternatively, the receiving chamber can of course be filled with solid material, which is in particular one piece and / or uniform material with the inner wall.

The invention further relates to an air-handling device which has a fluid deflection device according to the preceding embodiments.

Figur 1

eine schematische Darstellung einer Fluidumlenkungseinrichtung, die sich aus zwei Fluidverteilungselementen zusammensetzt,

Figur 2

eine Detaildarstellung eines der Fluidverteilungselemente,

Figur 3

eine Längsschnittdarstellung durch die Fluidumlenkungseinrichtung,

Figur 4

eine Ausgestaltung der Fluidumlenkungseinrichtung, bei welcher in einer Aufnahmekammer eine Querschnittsverstelleinrichtung angeordnet ist,

Figur 5

eine schematische Darstellung der Fluidumlenkungseinrichtung in einer zweiten Ausführungsform,

Figur 6

eine erste Ausführungsform eines lufttechnischen Geräts in schematischer Längsschnittdarstellung, wobei das lufttechnische Gerät über die Fluidumlenkungseinrichtung verfügt, sowie

Figur 7

eine zweite Ausführungsform des lufttechnischen Geräts.

The invention will be explained in more detail with reference to the embodiments illustrated in the drawings, without any limitation of the invention. Showing:

FIG. 1

a schematic representation of a fluid deflection device, which consists of two fluid distribution elements,

FIG. 2

a detailed view of one of the fluid distribution elements,

FIG. 3

a longitudinal sectional view through the fluid deflection device,

FIG. 4

an embodiment of the fluid deflection device, in which a cross-section adjustment device is arranged in a receiving chamber,

FIG. 5

a schematic representation of the fluid deflection device in a second embodiment,

FIG. 6

a first embodiment of a ventilation device in a schematic longitudinal sectional view, wherein the ventilation device has the fluid deflection means, and

FIG. 7

a second embodiment of the ventilation device.

The FIG. 1 shows a schematic representation of a fluid deflection device 1, as may be installed, for example, in an air handling unit 2, not shown here. The fluid deflection device 1 has an inner wall 3, an intermediate wall 4 and an outer wall 5. It basically consists of two fluid distribution elements 6 and 7, which adjoin one another directly in an imaginary parting plane 8.

It is at least somewhat recognizable that the outer wall 5 consists of two outer wall regions 9 and 10 adjoining in the axial direction and / or has these. The intermediate wall 4 has intermediate wall portions 11 and 12, which are spaced apart in the axial direction. The inner wall 3 in turn has inner wall regions 13 and 14, of which only the inner wall region 13 can be seen here. The inner wall portions 13 and 14 are analogous to the outer wall portions 9 and 10 in the axial direction directly adjacent to each other, so that the inner wall 3 and the outer wall 5 are each configured in the form of a continuous circular cylinder. By contrast, the intermediate wall regions 11 and 12 each form a separate circular cylinder.

In addition to the aforementioned walls 3, 4 and 5, the fluid deflection device 1 has a plurality of radial webs 15, of which only some are identified purely by way of example. The radial webs extend in the radial direction preferably continuously from the inner wall 3 to the outer wall 5, so connect them. In addition, the intermediate wall 4 is connected via the radial webs 15 on the one hand to the inner wall 3 and on the other hand to the outer wall 5.

The fluid deflection device 1 has two opposite sides in the axial direction. On a first side, a first inner fluid port 16 and a first outer fluid port 17 are provided. On the second side, however, (not visible here), a second inner fluid port 18 and a second outer fluid port 19. The inner fluid ports 16 and 18 are limited in the radial direction to the outside of the intermediate wall 4. The outer fluid connections 17 and 19 are seen in the radial direction between the intermediate wall 4 and the outer wall 5, so are bounded inwardly by the intermediate wall 4 and outwardly from the outer wall 5.

It is now provided that the first inner fluid port 16 is in fluid communication with the second outer fluid port 19 and is fluidly isolated from the second inner fluid port and of course also from the first outer fluid port 17. On the other hand, the first outer fluid connection 17 should be in fluid communication with the second inner fluid connection 18 and be fluidly separated from the second outer fluid connection 19 and, of course, also from the first inner fluid connection 16. The fluid connection between the first inner fluid port 16 and the second outer fluid port 19 is via at least a first flow chamber 20 and the fluid connection between the first outer fluid port 17 and the second inner fluid port 18 via at least one second flow chamber 21.

In the embodiment shown here, a plurality of first flow chambers 20 and a plurality of second flow chambers 21 are formed, which are seen alternately formed in the circumferential direction. The first flow chambers 20 and the second flow chambers 21 are indicated here merely by way of example and pass through the fluid deflection device 1 in each case starting from one of the fluid connections on the first side to another of the fluid connections on the other side. In the exemplary embodiment illustrated here, an inner space 22 (not visible here) delimited from the inner wall 3 in the radial direction is closed at least on one side by means of a cover 23 in the axial direction. Preferably, the interior 22 is closed on both sides by means of lids 23. The cover 23 or the cover 23 are in this case preferably designed in one piece and / or of the same material with the inner wall 3. The lid 23 may basically have any shape. For example, it is continuous flat, conical, frusto-conical or partially spherical, in particular hemispherical.

The FIG. 2 shows purely by way of example, the fluid distribution element 7. Clearly visible here is the parting plane 8, in which the outer wall portions 9 and 10 and the inner wall portions 13 and 14 adjacent to each other. It becomes clear that the fluid distribution element 7 has a multiplicity of radial webs 15 or radial web areas. Each two of the radial webs 15 defines between them one of the first flow chambers 20 or one of the second flow chambers 21. Preferably, each of the radial webs 15 defines in the circumferential direction, on the one hand one of the first flow chambers 20 and on the other hand one of the second flow chambers 21. It is further apparent that in Seen in the circumferential direction, the first flow chambers 20 alternate with the second flow chambers 21.

To form the flow chambers 20 and 21, two of the radial webs 15 are connected to each other by means of an inner flow guide wall 24 or an outer flow guide wall 25. Preferably, the inner flow guide walls 24 and the outer flow guide walls 25 alternate in the circumferential direction. Of each of the radial webs 15 so goes in the circumferential direction on the one hand, an inner flow guide wall 24, but no outer flow guide wall 25, and on the other hand, an outer flow guide wall 25, but no inner flow guide wall 24. In other words, each take exactly one of the inner flow guide walls 24 and exactly one of the outer flow guide walls 25 each have exactly one radial web 15 between them or directly adjacent to this.

The FIG. 3 2 shows a longitudinal section through the fluid deflection device 1 along a longitudinal center axis 26. The fluid deflection device 1 in the embodiment shown here on both sides each have a receiving chamber 27 or 28, which inwardly by a recession of the inner wall 3 in the axial direction, ie in the direction of the parting plane 8, is realized. The inner wall 3 has axially opposite end faces 29 and 30, the intermediate wall 4 in the axial direction opposite end faces 31 and 32 and the outer wall 5 in the axial direction opposite end faces 33 and 34 on.

It is clear that the end faces 31 and 33 on the one hand and the end faces 32 and 34 on the other hand in each case lie in a common plane, this plane being perpendicular to the longitudinal central axis 26. The end faces 29 and 30, however, are offset in the axial direction inwardly toward each other to form the receiving chambers 27 and 28. In the receiving chambers 27 and 28, an impeller 35 of a fan device 36 is arranged in each case. It can be provided that the wheels 35 are drivable by means of the same motor 37, which is arranged in the interior 22.

The flow chambers 20 and 21 can be thoughtfully divided into a first flow region, a second flow region and a third flow region, as viewed in the axial direction. In the first flow region, they become radially outside of the intermediate wall 4, in the second flow region radially inward from the inner wall 3 and radially outward from the outer wall 5 and in the third flow region radially inward from the intermediate wall 4 and bounded on the outside by the outer wall 5.

The FIG. 4 shows an alternative embodiment of the fluid deflection device 1. Basically, reference is made to the above statements and discussed only the differences. Instead of the fan device 36 with the impeller 35 and the motor 37, a cross-section adjustment device 38 is now at least partially arranged in the receiving chamber 27. The cross-section adjustment device 38 has an adjustable aperture 39, by means of which the flow cross-section of the first flow chamber 20 (in the embodiment illustrated here) is adjustable. Of course, the cross-section adjustment device 38 additionally or alternatively have a diaphragm, which serves to adjust the flow cross-section of the second flow chamber 21. The aperture 39 is adjustable, for example by means of a motor, which is arranged analogously to the motor 37 in the interior 22.

The FIG. 5 shows a schematic representation of the fluid deflection device 1 in a second embodiment. This is largely identical to the already described fluid deflection device 1 constructed so that reference is made to the above statements and will be discussed below only the differences. These are that the inner flow guide wall 24 and / or the outer flow guide wall 25 are now not only curved in the circumferential direction, but additionally arranged inclined. In other words, the inner flow guide wall 24, the outer flow guide wall 25 or both are set in the circumferential direction. This may be provided in addition to or as an alternative to the curvature. For example, the inner flow-guiding wall 24 and / or the outer flow-guiding wall 25 are formed in a planar manner in regions or lie partially in an imaginary plane. The plane region or the imaginary plane is now angled relative to the longitudinal center axis 26, thus enclosing with this an angle which is greater than 0 ° and less than 180 °.

The inclination of the inner flow guide wall 24 and / or the outer flow guide wall 25 is directed, for example, in a direction of rotation of a fluid flowing through the device 1 flow. In particular, the inclination of a direction of rotation of the respective nearest impeller 35 is directed counter to the extent to reduce the peripheral speed of the flow to reduce the peripheral speed of the conveyed by the impeller 35 fluid so downstream of the impeller 35. With such a configuration of the fluid deflection device 1, a more uniform flow is realized. For all embodiments of the fluid deflection device 1, it may be provided that the radial webs 15 are inclined and / or curved, in each case in the axial and / or radial and / or tangential direction. For example, the radial webs 15 or each of the radial webs 15 is inclined, in particular in the axial direction that a diffuser is formed, in particular so the first flow chamber 20 and / or the second flow chamber 21 (each) are designed diffuser-like and thus in the flow direction a larger Have expectant flow area. In other words, the first inner fluid port 16 has a smaller flow cross-section than the second outer fluid port 19 in fluid communication with it and / or the first outer fluid port 17 has a smaller flow cross-section than the second inner fluid port 18 in fluid communication with it a nozzle-like configuration may be provided, in which the ratios of the flow cross-sections are reversed. Alternatively or additionally, the radial webs 15 may be inclined in the circumferential direction and / or in the tangential direction. A curvature of the radial webs 15 can also be realized, in particular a curvature in the radial direction.

The FIG. 6 shows a first embodiment of the ventilation device 2, which passes through a wall 40. The ventilation device 2 has an inner connection 41 with an interior panel 42 on the one hand the wall 40. On the opposite side of the inner terminal 41 of the ventilation device 2, an outer terminal 43 with an outer panel 44 on the other hand, the wall 40 is provided. By means of the ventilation device 2, two flow paths 45 and 46 are realized. In the Durchströmungsweg 45 inside a circular filter 47 and on the outside a ring filter 48 and in the Durchströmungsweg 46 inside a ring filter 49 and the outside a circular filter 50 is provided. In both flow paths 45 and 46, a heat accumulator 51 and the fluid deflection means 1 are arranged. The heat storage 51 is preferably formed integrally for both flow paths 45 and 46 and is for example in the form of a ceramic heat storage, in particular a ceramic honeycomb heat storage before.

The FIG. 7 shows a second variant of the ventilation device 2. Reference is made to the above statements and only the differences are discussed. These lie in the fact that, instead of the heat accumulator 51, two partial heat accumulators 52 and 53 are provided, which are arranged in the flow direction on both sides of the fluid deflecting device 1. In other words, the partial heat storage 52 is inside or on the one hand and the partial heat storage 53 on the outside or on the other hand, the fluid deflection device 1 is provided. The flow paths 45 and 46 substantially correspond to those described above. In principle, it should be noted that the flow paths 45 and 46 of the ventilation device 2 can in principle be flowed through in any direction. For example, the ventilation device 2 is designed as a so-called push-pull device, in which each of the flow paths 45 and 46 is temporarily traversed in each case a first direction and temporarily in each one of the first direction opposite second direction.

Claims (15)

Fluid deflection device (1), with an inner wall (3), an intermediate wall (4) and an outer wall (5) which are each circular cylindrical with respect to a longitudinal central axis (26) of the fluid deflection device (1), wherein on a first axial side of the fluid deflection device (1 ) on a first radial side of the intermediate wall (4), in particular between the inner wall (3) and the intermediate wall (4), a first inner fluid connection (16) and on a second radial side of the intermediate wall (4), in particular between the intermediate wall ( 4) and the outer wall (5), a first outer fluid connection (17) and on a first axial side opposite the second axial side of the fluid deflection means (1) on the first radial side of the intermediate wall (4), in particular between the inner wall (3). and the intermediate wall (4), a second inner fluid connection (18) and on the second radial side of the intermediate wall (4), in particular between the intermediate wall (4) and the outer A second outer fluid port (19) is formed, wherein the first inner fluid port (16) is in fluid communication with the second outer fluid port (19) and fluidly isolated from the second inner fluid port (18) and the first outer port Fluid port (17) is in fluid communication with the second inner fluid port (18) and is fluidly separated from the second outer fluid port (19). Fluid diverter according to claim 1, characterized in that the fluid communication between the first inner fluid port (16) and the second outer fluid port (19) via at least a first flow chamber (20) and the fluid connection between the first outer fluid port (17) and the second inner Fluid connection (18) via at least one second flow chamber (21) is present. Fluid deflection device according to one of the preceding claims, characterized in that the first flow chamber (20) and / or the second flow chamber (21) each seen in the radial direction in a first flow area inside of the inner wall (3) or outside of the intermediate wall (4) and / or in a second flow area inside from the inner wall (3) and the outside of the outer wall (5), and / or in a third flow area on the inside of the intermediate wall (4) and on the outside of the outer wall (5) is limited. Fluidumlenkungseinrichtung according to any one of the preceding claims, characterized in that the inner wall (3), the intermediate wall (4) and the outer wall (5) via radial webs (15) are interconnected, wherein each two of the radial webs (15), the first flow chamber (20 ) and / or limit the second flow chamber (21) in the circumferential direction. Fluid deflection device according to one of the preceding claims, characterized in that the two each of the radial webs (15) on their first axial side facing end surfaces via a the inner wall (3) and the intermediate wall (4) interconnecting and spaced from the outer wall (5) inner flow guide wall (24) are interconnected and / or on their second axial side facing end surfaces via a the intermediate wall (4) and the outer wall (5) interconnecting and from the inner wall (3) spaced outer flow guide wall (25) are interconnected , Fluidumlenkungseinrichtung according to any one of the preceding claims, characterized in that the inner flow guide wall (24) and / or the outer flow guide wall (25) is curved in the circumferential direction, in particular continuously or only in one of the radial webs (15) adjacent curvature region, and / or tangentially in the radial webs (15) passes. Fluidumlenkungseinrichtung according to any one of the preceding claims, characterized in that the inner flow guide wall (24) and / or the outer flow guide wall (25) are inclined in the radial direction and / or in the tangential direction, in particular in opposite directions are inclined. Fluid deflection device according to one of the preceding claims, characterized in that the outer flow guide wall (25) to an axially inner end face of the intermediate wall (4) immediately adjacent and the inner flow guide wall (24) via a the intermediate wall (4) continuing connecting web at the end face the intermediate wall (4) attacks. Fluidumlenkungseinrichtung according to any one of the preceding claims, characterized in that the fluid deflection means (1) two adjacent to each other in the axial direction Axialbereiche, each of the Axialbereiche an inner wall portion (13,14) of the inner wall (3), an intermediate wall portion (11,12) of the intermediate wall (4), an outer wall portion (9,10) of the outer wall (5) and Radialstegbereiche the radial webs ( 15), the outer wall regions (9, 10), the inner wall regions (13, 14) and the radial web regions adjoining one another and the intermediate wall regions (11, 12) being aligned with one another in the axial direction. Fluid deflection device according to one of the preceding claims, characterized in that in each of the axial regions in the circumferential direction alternately an inner flow guide wall (24) and an outer flow guide wall (25) on the respective partition wall region (11,12) engage, so that the flow guide walls (24,25) the axial areas are arranged in rows spaced apart in the axial direction. Fluid deflection device according to one of the preceding claims, characterized in that each of the axial regions is in each case formed by a fluid distribution element (6, 7) and the fluid distribution elements (6, 7) are present as identical parts. Fluidumlenkungseinrichtung according to any one of the preceding claims, characterized in that the fluid distribution elements (6,7) are connected angularly offset with each other in the circumferential direction. Fluid deflection device according to one of the preceding claims, characterized in that the first inner fluid port (16) and the second inner fluid port (18) have the same flow cross-section or that the first outer fluid port (17) and the second outer fluid port (19) have the same flow cross-section. Fluid deflection device according to one of the preceding claims, characterized in that one of the first axial side facing end face (29) of the inner wall (3) offset in the axial direction in the direction of the second axial side and / or one of the second axial side facing end face (30) Inner wall (3) is arranged offset in the axial direction in the direction of the first axial side, in particular in each case for forming a receiving chamber (27,28), preferably for a fan device (36) and / or a Querschnittsverstelleinrichtung (38). Air-conditioning device (2), characterized by a fluid deflection device (1) according to one of the preceding claims.

Images