This application claims the benefit and priority of German Application No. 10 2021 113 247.9 filed May 21, 2021. The entire disclosure of the above application is incorporated herein by reference.
The invention relates to an air duct and an assembly for a fume extraction hood, wherein the duct extends substantially in a longitudinal direction, with a duct wall which encloses a flow cross-section.
Various types of air ducts for ventilating and exhausting buildings are known from the prior art. The task of an air duct is, for example, to remove the vapors produced when working in kitchens, especially when heating food and liquids, from the area of the kitchen to keep the working area free of odors and condensate.
Against the background of increasing environmental awareness and growing competitive pressure in a globalized economy, the aim of resource-saving production of air ducts is, on the one hand, to reduce the amount of material used and, on the other, to design the air ducts for the widest possible range of applications. An air duct is known, for example, from DE 10 2017 104 772 A1.
However, the air ducts known from the prior art have the disadvantage that individual fastening means must be provided in each case for additional functional elements to be accommodated in the air duct. Furthermore, depending on the duct element length, additional center support may be necessary, but this can vary between different installation situations.
It is therefore an aspect of the invention to provide an air duct in which different functional elements can be accommodated in a particularly simple manner.
Accordingly, an air duct is proposed which extends essentially in a longitudinal direction, with a duct wall which encloses a flow cross section and has on its inside a fastening means for variably positionable fastening in the longitudinal direction of the duct of at least one functional element which can be accommodated in the air duct. The air duct can be designed in particular as a flat duct. The flat duct can have a transverse dimension which is larger than a height dimension of the flat duct. As a result, the duct wall enclosing the flat duct may have a total of four wall sections, of which the wall sections extending in the transverse direction are parallel to one another and the wall sections extending in the vertical direction are parallel to one another. The wall sections may each merge into each other via rounded corners. The air duct may alternatively be designed as a round duct. The inner side of the duct wall faces the flow cross section in particular. The functional element may be an element that technically interacts with the air duct. The functional element may further be an element extending the technical function of the air duct. For example, a support web, cable duct or sound damping element or a combination thereof may be a receivable functional element. The air duct may further comprise two oppositely arranged fastening means. This allows a functional element accommodated in the duct to be fixed to opposite inner sides of the duct. In particular, the opposing fastening means can be arranged in alignment with one another.
It may be provided that the duct wall has a wall thickness that varies over its course. For example, in the flat duct, the wall thickness in the rounded corners may be less than in the straight wall sections. It may also be provided that the wall thickness in the straight wall sections increases gradually towards the center in each case. In the flat duct design, it may further be provided that the maximum thickness of the wall sections extending in the transverse direction is greater than the maximum thickness of the wall sections extending in the vertical direction. For example, the wall thickness in the rounded corners may be between 0.8-1.6 mm, preferably between 1.0-1.4 mm, particularly preferably 1.2 mm. The maximum wall thickness of the wall sections extending in the height direction can be, for example, between 1.0-1.5 mm, preferably between 1.2-1.3 mm, particularly preferably 1.25 mm. The maximum wall thickness of the wall sections running in the transverse direction can be, for example, between 1.5-2.1 mm, preferably between 1.7-1.9 mm, particularly preferably 1.8 mm. Starting from the point of maximum wall thickness in the center of the wall sections running in the transverse direction, the corresponding wall sections on the outside of the flat duct can each extend in the direction of the corners with an inclination of between 0.2-0.6°, preferably between 0.3-0.5°, particularly preferably 0.4°. The height extension of the flat duct can be, for example, 80-92 mm, preferably 84-88, particularly preferably 86.6 mm. The transverse extent of the flat duct can be, for example, 200-240 mm, preferably 210-230 mm, particularly preferably 219.6 mm. The inner radius of the rounded corners may be, for example, 15-25 mm, preferably 18-22 mm, particularly preferably 20 mm.
The air duct can also have a riblet structure on its inside. Particularly advantageously, these can reduce frictional resistance on surfaces subject to turbulent overflow. The riblets can be designed as fine ribs with sharp tips. It may be provided that the longitudinal axes of the riblets or ribs are aligned in the direction of flow.
It may also be provided that the air duct has stiffening ribs running in the longitudinal direction on its outer side. The distance between the stiffening ribs can be smaller in the area of the rounded corners than in the area of the straight wall sections. The distance between the stiffening ribs can decrease gradually towards the center of the straight wall sections. For example, the maximum spacing of the stiffening ribs on the transversely aligned wall sections of the flat duct can be between 5-15 mm, preferably between 8-12 mm, particularly preferably 10 mm. Furthermore, the maximum spacing of the stiffening ribs on the wall sections of the flat duct aligned in the height direction can be between 3-7 mm, preferably between 4-6 mm, particularly preferably 5 mm.
In the design as a flat duct with an essentially rectangular flow cross section, the fastening means can preferably be arranged on the inside of one of the longer wall sections, in particular the transverse walls. When using the fastening means for fastening a support web, the flat duct can be supported particularly advantageously at its structurally weakest point, in which the support web is supported on the opposite wall.
The fastening means can be designed to prevent movement of the functional element from the duct wall section comprising the fastening means in the direction of the duct interior. This can prevent slipping or displacement of the functional element along the height axis, in particular in the direction of the duct center or the opposite wall, of the air duct. For this purpose, the fastening means can have a holding device which can be gripped behind by a functional element inserted into the air duct.
The fastening means can also be designed to prevent movement of the functional element in a transverse direction of the duct wall section comprising the fastening means. This can prevent slippage or displacement of the functional element along the transverse axis of the air duct, in particular along the duct wall section comprising the fastening means. For this purpose, the fastening means can have a holding device which laterally supports a functional element inserted into the air duct. In particular, the fastening means can have a holding device that fixes a functional element inserted into the air duct in the transverse direction from both sides.
Furthermore, the fastening means can be designed to prevent twisting of the functional element about an axis of rotation perpendicular to the plane of the duct wall section comprising the fastening means. Thus, twisting of the functional element in or parallel to the plane of the duct wall section comprising the fastening means can be prevented. For this purpose, the fastening means can have a holding device which supports a functional element inserted into the air duct in the transverse direction from both sides, the support points being offset from one another in the longitudinal direction of the duct.
In addition, the fastening means can be designed to prevent twisting of the functional element about an axis of rotation perpendicular to the flow cross section. In this way, twisting of the functional element parallel to the duct wall can be prevented. For this purpose, the fastening means can have a holding device which can be gripped behind by a functional element inserted into the air duct at at least two support points spaced apart from one another in the transverse direction.
The fastening means can be designed to prevent twisting of the functional element about an axis of rotation perpendicular to the longitudinal duct section. This can prevent twisting of the functional element about the transverse axis. For this purpose, the fastening means can have a holding device which can be gripped behind by a functional element inserted into the air duct at least two support points spaced apart from one another in the longitudinal direction.
Furthermore, the fastening means can have at least one linear rail extending at least in sections in the longitudinal direction of the duct. In particular, the linear rail can be arranged centrally on the duct wall comprising it. The linear rail can extend over the entire length of the duct.
In addition, the fastening means can have at least two undercut latching sections, whereby the functional element can be pushed onto the fastening means in the longitudinal direction of the duct. For example, the at least one linear rail can have a longitudinal groove in which the two latching sections are designed to face one another in an undercut manner. Alternatively, the at least one linear rail can have two latching sections facing away from each other in the transverse direction on its outer sides.
The fastening means can comprise two parallel linear rails, each of which has an undercut latching section. For simplified threading of the functional element, the two linear rails can have a widening at the ends of the duct piece lying in the longitudinal direction or can be slightly spaced apart. In a corresponding manner, the latching sections can also be widened at the widened ends.
The at least one linear rail may have a first section extending substantially perpendicularly away from the duct wall and an adjoining second section extending substantially parallel to the duct wall.
The undercut latching sections can point towards each other. Alternatively, the undercut latching sections can point away from each other.
The fastening means can be formed integrally with the duct wall or molded onto it. The duct can be produced by extrusion, for example.
It may be envisaged that the air duct is designed as a flat duct and has a varying wall thickness, wherein the wall thickness in the corner regions is less than in the straight wall sections, and wherein the wall thickness increases towards the center of the straight wall sections.
The invention further relates to an assembly comprising an air duct according to any one of the preceding claims and a functional element mounted in the air duct.
The functional element can have two snap-in legs which engage behind the undercut latching sections to fasten the functional element in the air duct. To mount the functional element, it can be pushed onto the fastening means open to the end faces via one of the end faces of the air duct. The snap-in legs can be connected to each other via two latching or snap-in legs connecting them. When the snap-in legs are installed in the latching sections, the snap-in legs can be slightly pretensioned. This ensures secure fastening of the functional element in the air duct.
It may further be provided that the functional element comprises an air duct supporting member extending between the fastener and the duct wall section opposite the fastener. It may be provided that the support element slightly biases the opposing supported duct walls toward each other. If the air duct has two opposite fastening means, the support element can be inserted into the respective fastening means accordingly with opposite snap-in legs. If only one fastening means is provided in the flat duct, the support element can be designed in such a way that it has a force introduction surface on its side opposite the fastening means. The force introduction surface can be designed in particular parallel to the duct wall adjacent thereto, so that the force introduction surface lies flat against the duct wall associated therewith. The provision of a force introduction surface results in improved support or anti-tilt protection of the support element, whereby the support element is supported in accordance with the third Euler buckling case and thus has a higher critical buckling load. Further, the support element may be formed as a support web having a web portion extending substantially parallel to the height extent of the duct. The web section can have a thickening towards the center of the web. This is where the highest stresses can occur. The web center can have a thickness of 1.9-2.1 mm, preferably 1.95-2.05, particularly preferably 1.99 mm.
In addition, the functional element can have a cover extending between the undercut latching sections, by means of which a cable duct is formed between the cover and the duct wall section covered by it, separated from the flow area and extending in the longitudinal direction of the duct. The cable duct can be designed in such a way that, for example, a compressed air hose of 8 mm diameter and a 4×6 mm cable can be accommodated in it simultaneously. The cover can extend between and/or be formed onto the two snap-in legs. In particular, the cover may be semi-circular in shape. Furthermore, the cover and the support web can be designed as a combination. In this case, the support web above the cover can extend away from the latter. The support web can be integrally formed with the cover. The semicircular design of the cover in combination with the support element provides particularly good stress distribution. Immediately above the cover, the web can have a thickness of between 1.2-1.4 mm, preferably 1.25-1.35 mm, particularly preferably 1.28 mm. Immediately below the force introduction surface, the web can have a thickness between 1.15-1.35 mm, preferably 1.2-1.3 mm, particularly preferably 1.23 mm.
The surfaces of the functional elements assigned to the flow areas of the air duct can each be covered with a riblet structure.
Further features, advantages and characteristics of the invention can be seen in the following description of preferred embodiments of the invention with reference to the accompanying drawings, in which shows:
In
An assembly 309 of a flat duct 316 and a functional element 304 received therein is shown in
The features of the invention disclosed in the foregoing description, in the drawings as well as in the claims may be essential to the realization of the invention both individually and in any combination.
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