DE102007019538B4 - Air guide element for an aircraft air conditioning system - Google Patents

Abstract

Air guiding element (10) for an aircraft air conditioning system having an air inlet (12) and a main body (14) connecting the air inlet (12) to an air outlet (16), wherein at least one of a cross section of the main body (14) is provided in a lateral surface of the main body (14). narrowing recess (24) is formed, which is arranged in the flow path of the air guide element (10) via the air inlet (12) supplied air and having a defined Luftleitgeometrie, and wherein the recess (24) has an air flow distribution wall (26) so positioned in that it is flown by the air supplied via the air inlet (12), characterized in that the air flow distribution wall (26) extends substantially perpendicular to an area of the lateral surface of the base body (14) which is adjacent to the air flow distribution wall (26).

Description

The The invention relates to an air guide element for one Aircraft air conditioning system. Furthermore, the invention relates to a with a such air guide element equipped aircraft air conditioning.

One from the US 6,752,712 B1 known aircraft air conditioning system comprises a number of air guide elements, which is supplied via an air inlet, a conduit system of the aircraft air conditioning system by flowing air. The air guide elements serve to provide a desired distribution of air flowing through the line system of the aircraft air conditioning system before the air exits the air guide elements via an air outlet and, for example, is directed into a passenger cabin of the aircraft. An Indian US 6,752,712 B1 described air guide element comprises a cavity enclosing body, which connects the air inlet of the air guide element with an air outlet of the air guide element. In order to ensure a proper distribution of the air flow supplied to the air flow element in the body, a guide vane is arranged in the interior of the main body. The vane is formed in the form of a separate component and is fastened in a desired position on an inner surface of the base body in the manufacture of the air guide element. The production of such an air guide element is relatively expensive and therefore expensive.

The EP 0 292 033 A2 describes an air handling element provided for use in an aircraft. The air guide element comprises an air inlet formed in the form of a nozzle, a base body and an air outlet formed in the form of a nozzle. A depression is provided in the base body whose shape influences the velocity and the volume flow of the air flowing out of the air guide element via the air outlet.

The JP 11-020796 A discloses an air outlet member for use in an aircraft air conditioning system that includes a plurality of side-by-side air ducts. The air ducts each have a horizontally oriented air inlet and a vertically oriented air outlet. Between the air inlet and the air outlet, the air flows along an inclined baffle.

The The invention is directed to the object, one for use in a Aircraft air conditioning system to provide suitable air guide element, easy and inexpensive can be produced and optimal control of the air flow in the Interior of the air guide element allows.

These The object is achieved in each case by the features of the independent claims.

to solution This object has an inventive air guide element for an aircraft air conditioning an air inlet and an air inlet with an air outlet connecting and a cavity enclosing the base body, wherein in a lateral surface of the basic body at least one a cross-section of the body narrowing recess is trained. The recess is in the flow path of the air guide element over the Air inlet supplied Air is arranged and has a defined, that is one to the desired airflow through the air guide element adapted air conduction geometry on. The distribution of the air guide element according to the invention over the Air inlet supplied Air flow can controlled as desired with the aid of the air guide geometry of the recess become. Thus, in the air guide element according to the invention to the use a formed in the form of a separate component vane be waived. The air guide element according to the invention can therefore be simple Be made in a manner that results in considerable Achieve cost savings. The air guide element according to the invention can from any material, such. B. a lightweight glass fiber reinforced Material or a plastic material, in a cost effective manner and processed in one step by injection molding can be. By waiving the in the form of a separate component Trained vane is distinguished by the air guide element according to the invention about that In addition, by a particularly advantageous for use in aircraft low weight.

at the air guide element according to the invention can the Luftleitgeometrie trained in the lateral surface of the body Deepening in dependence the shape of the air guide element as well as in dependence the specific application, d. H. for example, depending on the flow volume and the pressure of the air guide element over the Air inlet supplied airflow be designed to the desired Distribution of air flow inside the air guide element to realize. Since the design of the Luftleitgeometrie on relatively simple Way to the specific requirements of the distribution the air flow inside the air guide element can be customized for a particular application stands out the air guide element according to the invention by excellent fluidic Properties off.

In addition, the design of the Luftleitgeometrie in the air guide element according to the invention in a simple manner in terms of acoustic properties of the air guide element can be optimized.

The in the lateral surface of the main body of the inventive air guide element formed recess is formed to have an air flow distribution wall which is positioned so as to be separated from the above Air inlet supplied Air streamed and which is substantially perpendicular to one to the air flow distribution wall extending adjacent area of the lateral surface of the body. By such a configuration of the Luftleitgeometrie the depression is an abrupt narrowing of the cross section of the main body of the Air guidance element in the area of the air flow distribution wall realized and thereby an optimal control of the air flow inside of the air guide element allows. The airflow distribution wall can either be arranged so that the air guide element over the Air inlet supplied Air substantially perpendicular to the air flow distribution wall meets. Alternatively, however, it is also possible to use the airflow distribution wall to be arranged so that the air guide element over the Air inlet supplied Air hits the airflow distribution wall at an acute angle or even at least in a region of the air flow distribution wall flows substantially parallel to the air flow distribution wall.

The Air duct element according to the invention can only one in the lateral surface of the basic body formed cross-sectional narrowing depression with a defined Have Luftleitgeometrie. However, the air guide element can also with several in the lateral surface of the basic body trained cross-sectional narrowing and a defined Luftleitgeometrie be formed having recesses. The depressions can be in only a portion of the lateral surface, d. H. for example, only in a front or only in a back Area of the lateral surface be educated. Alternatively, however, two can each other opposing Areas or areas the lateral surface with a defined Luftleitgeometrie having depressions be provided.

Preferably forms the narrowed by the recess cross-section of the body a defined gap to the flow with the air guide element according to the invention fed through the air inlet Air. The geometry of this gap can each be adapted to the specific Requirements for the distribution of the air flow inside the air guide element be customized for a particular application.

at a preferred embodiment the air guide element according to the invention has the in the lateral surface of the basic body of the air guide element well formed further a transitional wall, the one the interior of the body facing edge of the air flow distribution wall with one to the transition wall adjacent area of the lateral surface of the body connects.

The transition wall For example, it may be shaped to pass through the depression narrowed cross section of the main body starting from the interior of the body facing edge of the Air flow distribution wall along the transition wall continuously expanded. By such a design of the Luftleitgeometrie in the lateral surface of the basic body of the air guide element trained well will be a particularly good distribution of the air guide element over the Air inlet supplied Air inside the air guide element allows. About that can out particularly good acoustic properties can be realized.

As already mentioned, The design of the airflow geometry of the recess can be adapted to the shape of the air guide element as well as in a special application to the distribution of Air inside the air guide element as well as the to the air guide element adjusted acoustic requirements. For example can the air flow distribution wall arranged on a side facing the air inlet side of the recess be. The the air guide element on the Air inlet supplied Air then hits immediately after it enters the air duct on those in their flow path arranged air flow distribution wall and is thereby distributed in the interior of the air guide element.

Further For example, the recess may be a plurality of at an angle to each other have extending sections. In such an embodiment can the air supplied to the air inlet of the air guide element in a desired Area of the air guide element directed.

Furthermore the depression may be one opposite the air inlet and substantially perpendicular to the flow direction the the air guide element over the Air inlet supplied Air arranged first section include. From this first section At least a second section may extend, essentially parallel to the flow direction the the air guide element over the Air inlet supplied Air, d. H. is arranged perpendicular to the first section. Of the second section of the recess may, for example, in the direction extend the air inlet.

Alternatively, the indentation may be an in Having direction of the air inlet of the air guide element tapered shape. The air supplied to the air inlet of the air guide element then impinges immediately after its entry into the air guide element on the tapered region of the recess. By such a design of the air flow distribution wall, a particularly good distribution of the air guide element supplied air is made possible in the outer regions of the body.

It is also conceivable, the air guide element according to the invention with at least form a depression having a substantially cylindrical Luftleitgeometrie having. Preferably, the air guide element according to the invention with a plurality of substantially cylindrical Wells provided for a turbulence of the air guide element over the Air inlet supplied Take care of the air. The number of formed in the air guide element essentially cylindrical Recesses is due to the geometry of the air guide element and the desired air distribution in the air guide element customized.

at the air guide element according to the invention The air intake can be in the form of a body connected to the body Zuluftstutzens be formed. One in the form of a supply air outlet trained air intake can be on special simple and comfortable Way connected to a pipeline of the aircraft air conditioning become. The shape and the cross-section of the supply air connection can thereby the shape and the cross-section of connecting with the supply air pipe Piping to be adjusted, as in the air guide element according to the invention the air distribution in the interior of the air guide element through the air flow distribution wall is controlled and thus independent from the shape of the air inlet.

One Air outlet of the air guide element according to the invention is, however, preferably in the form of a in the lateral surface of the Basic body provided Formed gaps. The through the air flow distribution wall in the interior of the air guide element distributed air can then evenly out the slit-shaped emerge trained air outlet. The air outlet of the air guide element can only in the form of a simple in the lateral surface of the the body designed cleft be designed. Alternatively, the air outlet additionally one formed by the in the lateral surface of the body Have gap extending extension.

at a preferred embodiment the air guide element according to the invention is in the region of the air outlet in the body of the air guide element arranged a pinhole. The pinhole causes a backwater of the the air guide element flowing through Air and thus serves to control the distribution of the air outlet exiting air flow. In terms of its shape, the pinhole is at a cross section adapted to the air outlet. The pinhole can have a diaphragm surface, in the majority of over the aperture area distributed openings is arranged. The shape and size of the openings in the panel can be applied to the distribution of the air flow exiting the air outlet Requirements are adjusted.

Preferably is arranged at the pinhole a plurality of webs, which is substantially parallel to each other between each other Sections of the lateral surface of the basic body from a side facing the air outlet side of the diaphragm surface in the direction extend the air outlet. By trained at the pinhole Webs, the air outlet into a plurality of air outlet sections divided, reducing the air flow straightens and thus the air distribution along the air outlet is optimized.

The Air duct element according to the invention can comprise a first and a second air outlet. Furthermore, can the recess have such a Luftleitgeometrie that the the air guide element over the Air inlet supplied Air distributed in the direction of the first and the second air outlet becomes. Such an air guide element can for example, advantageously as a branch line element used in a piping system of an aircraft air conditioning system become.

A Aircraft air conditioner according to the invention comprises at least one air guide element described above.

preferred embodiments an air guide element according to the invention will now be with reference to the attached schematic drawings closer explains of which

1 shows a three-dimensional representation of a first embodiment of an air guide element according to the invention,

2 a three-dimensional representation of the air guide element according to 1 rotated by 180 °,

3 a broken-away view of the air duct element after 2 shows,

4 a three-dimensional representation of a second embodiment of an inventive proper air guide element shows

5 shows a three-dimensional representation of a third embodiment of an air guide element according to the invention,

6 shows a three-dimensional representation of a fourth embodiment of an air guide element according to the invention, and

7 shows a three-dimensional representation of a fifth embodiment of an air guide element according to the invention.

One in the 1 to 3 shown air guide element 10 , which is intended for use in an aircraft air conditioning system, comprises an air inlet connectable to a pipeline of the aircraft air conditioning system 12 , The air intake 12 is in the form of a base body 14 of the air guide element 10 extending Zuluftstutzens formed. A shape and a cross section of the Zuluftstutzens are in a shape and a cross-section of the air inlet 12 of the air guide element 10 adapted to be connected pipe of the aircraft air conditioning.

The defined by a lateral surface and enclosing a cavity body 14 of the air guide element 10 has one in an air outlet 16 opening first section 18 as well as towards the air inlet 12 rejuvenating second section 20 on. The air outlet 16 is through a in the lateral surface of the body 14 formed gap and extending from the gap extension section 22 educated.

Like from the 1 and 3 it can be seen is in the lateral surface of the body 14 a a cross section of the body 14 narrowing depression 24 provided, which has a defined Luftleitgeometrie. 2 clarifies that in the lateral surface of the body 14 just a depression 24 is provided. In an in 2 shown area of the lateral surface of the body 14 that in the 1 and 3 shown, with the recess 24 provided area of the lateral surface of the body 14 is opposite, thus no recess is formed.

Alternatively, in the lateral surface of the air guide element main body 14 but also several the cross-section of the body 14 narrowing and a defined Luftleitgeometrie having depressions 24 be educated. The wells 24 can be formed in only one region of the lateral surface, ie, for example, only in a front side or only in a rear region of the lateral surface. Alternatively, however, two opposing areas or surfaces of the lateral surface with a defined Luftleitgeometrie having depressions 24 be provided.

On her the air intake 12 of the air guide element 10 facing side has the recess 24 an airflow distribution wall 26 on. The airflow distribution wall 26 extends substantially perpendicular to a to the air flow distribution wall 26 adjacent area of the lateral surface of the body 14 , By such a configuration of the air flow distribution wall 26 becomes an abrupt narrowing of the cross section of the main body 14 realized. An interior of the main body 14 facing edge 28 the flow distribution wall 26 is over a transitional wall 30 with one to the depression 24 adjacent area of the lateral surface of the body 14 connected. The transition wall 30 is shaped so that the through the flow distribution wall 26 narrowed cross section of the main body 14 starting from the interior of the body 14 facing edge 28 the air flow distribution wall 26 again continuously expanded.

Through the air intake 12 into the main body 14 of the air guide element 10 supplied air with a direction indicated by an arrow P flow direction hits when entering the first portion of the body 11 on the flow distribution wall 26 and is thereby deflected, as indicated by the arrows P _ab . Part of the air flows along the flow distribution wall 26 while another part of the air flows through a defined gap, through which through the recess 24 narrowed cross section of the main body 14 is formed. As a result, an optimal distribution of the air guide element 10 over the air intake 12 supplied air in the body 14 of the air guide element 10 guaranteed. At the same time, the design of the air conduction geometry in the lateral surface of the base body 14 trained depression 24 excellent acoustic properties of the air guide element 10 will be realized.

How out 3 is apparent, is in the area of the air outlet 16 in the main body 14 of the air guide element 10 a pinhole 38 to control the distribution of the air outlet 12 arranged exiting air flow. The pinhole 38 has an aperture surface in which a plurality of openings is formed. Furthermore, the pinhole includes 38 a plurality of webs 40 , which are substantially parallel to each other between opposing portions of the lateral surface of the body 14 from one of the air outlet 16 facing side of the diaphragm surface in the direction of the air outlet 16 extend. By the at the aperture 38 trained bridges 40 becomes the air outlet 20 divided into a plurality of air outlet sections, whereby a straightening of the air flow and thus optimum distribution of the air outlet 16 exiting air flow is ensured. The from the air outlet 16 of the air guide element 10 exiting air flow can be supplied for example to an aircraft passenger cabin.

This in 4 shown air guide element 10 is different from the one in the 1 to 3 represented component substantially by the shape of its body 14 and the shape of the Luftleitgeometrie in the lateral surface of the body 14 trained depression 24 , The in the lateral surface of the body 14 trained deepening 24 has a first portion, which is substantially perpendicular to a direction indicated by the arrow P flow direction of the air guide element 10 supplied air extends. A second section of the well 24 on the other hand, it extends in the direction of the air inlet 12 of the air guide element 10 essentially parallel to the flow direction of the air guide element 10 supplied air.

About the air intake 10 into the main body 14 of the air guide element 10 incoming air hits the side of the flow distribution wall 26 , Part of the air, as indicated by the arrows P _ab , along the flow distribution wall 26 while another part of the air in turn flows through a defined gap passing through the depression 24 narrowed cross section of the main body 14 is formed. By such a design of the Luftleitgeometrie in the lateral surface of the body 14 trained depression 24 can be in the main body 14 entering air into one in the 4 left, ie one from the air inlet 12 removed area of the body 14 be guided, so that despite the asymmetrical arrangement of the air inlet 12 an optimal distribution of the air inside the body 14 of the air guide element 10 is guaranteed. Incidentally, the structure and operation of the in 4 illustrated air guide element 10 the structure and functioning of the in the 1 to 3 shown component.

At the in 5 illustrated air guide element 10 is the Luftleitgeometrie in the lateral surface of the body 14 trained depression 24 so chosen that the recess 24 one in the direction of the air inlet 12 having tapered shape. Through the air intake 12 in the air guide element 10 supplied air is thereby, as indicated by the arrows P _ab , partly along the air flow distribution wall 26 in outer areas of the body 14 and passed in part through a defined gap through which through the recess 24 narrowed cross-section of the body 14 is formed. By such a configuration of the Luftleitgeometrie in the lateral surface of the body 14 trained depression 24 is an optimal air distribution in an air guide element 10 with a large body 14 allows. Incidentally, the structure and operation of the air guide element correspond 10 according to 5 the structure and functioning of the in the 1 to 3 shown component.

At the in 6 shown air guide element 10 is the Luftleitgeometrie in the lateral surface of the body 14 trained depression 24 , similar to the one in 5 shown component, chosen so that the recess 24 one in the direction of the air inlet 12 having tapered shape. Unlike the air guide element according to 5 is the depression 24 at the in the 6 illustrated air guide element 10 but not substantially symmetrical with respect to the body 14 arranged but is in one with the air inlet 12 connected, in the 6 right area of the main body 14 educated. By such a configuration of the recess 24 is despite the asymmetrically arranged air intake 12 a indicated by the arrows P _from good air distribution in the direction of one of the air inlet 12 removed, in the 6 left area of the main body 14 guaranteed. Incidentally, the structure and operation of the air guide element correspond 10 according to 6 the structure and functioning of the in the 1 to 3 shown component.

At the in 7 shown air guide element 10 has the in the lateral surface of the body 14 trained depression 24 a substantially perpendicular to the direction indicated by the arrow P flow direction of the air guide element 10 fed air extending first section and a second section which extends at an angle to the first section in the direction of the air inlet 12 extends. Unlike the one in 4 shown component, the second portion of the recess extends 24 but not in the second section 20 of the basic body 14 but is exclusively in the first section 18 of the basic body 14 arranged. Through the air intake 12 in the air guide element 10 incoming air hits, as indicated by the arrows P _ab , on the air flow distribution wall 26 and becomes part along the air flow distribution wall 26 in one of the air intake 12 removed, in 7 left area of the main body 14 and guided in part by a defined gap through which through the recess 24 narrowed cross section of the main body 14 is formed. Incidentally, the structure and operation of the air guide element correspond 10 according to 7 the structure and functioning of the in the 1 to 3 shown component.

Claims (11)

Air guiding element ( 10 ) for an aircraft air conditioning system with an air intake ( 12 ) as well as the air intake ( 12 ) with an air outlet ( 16 ) connecting body ( 14 ), wherein in a lateral surface of the main body ( 14 ) at least one a cross section of the base body ( 14 ) narrowing depression ( 24 ) is formed in the flow path of the air guide element ( 10 ) via the air inlet ( 12 ) is arranged and has a defined Luftleitgeometrie, and wherein the recess ( 24 ) an air flow distribution wall ( 26 ) positioned so as to be separated from the one via the air inlet ( 12 ) is supplied to the supplied air, characterized in that the air flow distribution wall ( 26 ) substantially perpendicular to one to the air flow distribution wall ( 26 ) adjacent region of the lateral surface of the basic body ( 14 ). Air guide element according to claim 1, characterized by at least two depressions ( 24 ), which in opposite areas of the lateral surface of the Grundköpers ( 14 ) are formed. Air guide element according to claim 1 or 2, characterized in that through the recess ( 24 ) narrowed cross-section of the main body ( 14 ) a defined gap to the flow through the air inlet ( 12 ) forms supplied air. Air guide element according to one of claims 1 to 3, characterized in that the recess ( 24 ) a transitional wall ( 30 ) having a the interior of the body ( 14 ) facing edge ( 28 ) the air flow distribution wall ( 26 ) with one to the transition wall ( 30 ) adjacent region of the lateral surface of the basic body ( 14 ) connects. Air guide element according to claim 4, characterized in that the transition wall ( 30 ) is shaped so that through the depression ( 24 ) narrowed cross-section of the main body ( 14 ) starting from the interior of the body ( 14 ) facing edge ( 28 ) the air flow distribution wall ( 26 ) along the transition wall ( 30 ) continuously expanded. Air guide element according to one of claims 1 to 5, characterized in that the recess ( 24 ) is cylindrical. Air guide element according to one of claims 1 to 6, characterized in that the air inlet ( 12 ) in the form of a with the main body ( 14 ) connected Zuluftstutzens and / or the air outlet ( 16 ) in the form of a in the lateral surface of the body ( 14 ) formed gap is formed. Air guide element according to one of claims 1 to 7, characterized in that in the region of the air outlet ( 16 ) in the body ( 14 ) a pinhole ( 38 ) for controlling the distribution of the air outlet ( 16 ) Exiting air flow is arranged. Air guide element according to claim 8, characterized in that at the pinhole ( 38 ) a plurality of webs ( 40 ) is arranged, which are parallel to each other between opposing portions of the lateral surface of the base body ( 14 ) from an air outlet ( 16 ) facing side of a diaphragm surface in the direction of the air outlet ( 16 ). Air guide element according to one of claims 1 to 9, characterized in that the air guide element ( 10 ) a first and a second air outlet ( 16 ) and the recess ( 24 ) has an air guide geometry such that the air inlet ( 12 ) supplied air in the direction of the first and the second air outlet ( 16 ) is distributed. Aircraft air conditioning system, characterized by at least one air guiding element ( 10 ) according to one of claims 1 to 10.