CH701880A2 - Air guiding system for ventilating rooms of building, has channel elements comprising cut-away portion at front end surface, where portion is open at contact surfaces and accommodates fixing units when elements are axially pushed together - Google Patents

Abstract

The system has channel elements (32) attached to each other by rigid tubular connectors (42), and fixing units (46, 48) for mounting the system in a room. The connectors are insertable into an axially continuous inner channel of the channel elements, and are mountable at a wall or ceiling of the room by the fixing units. The elements are made of expanded plastic i.e. expanded polystyrene, and have a cut-away portion (62) at a front end surface, where the cut-away portion is open at contact surfaces (38) and accommodates the fixing units when the elements are axially pushed together.

Description

The invention relates to an air ducting system for ventilation of rooms of a building.

For ventilating closed interiors of a building air ducting systems are used, on the one hand supply coming from a central supply air in rooms to be ventilated and distribute in these and on the other hand suck exhaust air from these rooms to the central unit. The central unit draws in outside air for the supply air lines and transports the exhaust air as exhaust air to the outside. Preferably, the central device has a heat exchanger in order to heat the intake air through the warm exhaust air. In most cases, the supply air is supplied to the living room and bedrooms, while the exhaust air is sucked into the bathroom and kitchen. This creates a slight pressure gradient from the living rooms and bedrooms to the odor and moisture-laden rooms, which counteracts the spread of odors and moisture from these rooms. Such an air guide system is described for example in DE 20 2008 008 005 U1.

In the construction of new buildings such air ducts can be integrated into the building walls. In the renovation and retrofitting of old buildings and in particular of inhabited or used rooms, this is practically impossible, as this would be associated at least with significant construction work and interventions in the building fabric. It is therefore known to install in such cases the retrofitted air ducts horizontally in the corner of the ceiling and wall or vertically in a corner of the room. To minimize the visual disturbance of the air duct system, suspended ceilings or covers can be used, but this is only possible if the room height is suitable. In other cases, the air ducts are covered by veneers that form a transition, for example, from the ceiling to the wall of the room and are adapted to the room in terms of design, color, texture and / or profiling. Such an air guidance system is described for example in DE 20 2008 006 542 U1. However, this system is complicated to manufacture and assembly, since the air ducts and the veneers are made separately and must be mounted separately.

The invention is based on the object to provide an air duct system for ventilation of rooms of a building available, which is inexpensive to produce, can be quickly and easily retrofitted in existing rooms and allows a visually pleasing interior design.

This object is achieved according to the invention by an air-guiding system having the features of patent claim 1.

Advantageous embodiments and modifications of the invention are specified in the dependent claims.

The inventive air duct system is composed of a few simple unitary components, namely channel elements and connectors. The channel elements are molded parts made of foamed plastic, which can be produced in a uniform length and have an axially continuous inner channel for air guidance. The channel elements have on their outside two perpendicular abutting planar contact surface, with which the channel elements can be inserted into the corner edge between the ceiling and wall of the room or possibly in the vertical corner edge between two walls. The remaining outer circumferential surface of the channel elements, which then faces the room when the channel element is mounted, can be selected and designed according to the room ambience. This space facing the room can be painted, cleaned, wallpapered, tiled or the like according to the design of the wall or the ceiling. The production of channel elements made of foamed plastic has the advantage that a single molded part both forms the channel for the air duct and the heat insulation for the air guided in the channel and allows the optical design without additional veneers.

The individual channel elements are joined together axially by means of the connector, so that the respective space dimensions corresponding channel lengths can be made. The connectors may be conveniently inserted into the inner channel of the channel members, with two channel members each being slid onto the connector from the opposite sides. By the fit of the connectors in the inner channels of the channel elements, the abutting channel elements are sealed together by the connector to the outside. The connectors are formed with fasteners that allow the connectors to be mounted to the wall or ceiling of the room. The connectors thus fulfill the dual function of connecting and sealing the axially abutting channel elements and also to secure these channel elements to the wall or ceiling of the room. The channel elements pushed onto the connector from both sides abut each other with their axial end faces, so that the connector is completely covered from view from the room side and the connector and the fastening of the channel elements are invisible.

Preferably, the inner channel of the channel elements has a circular cross-section and the connectors are accordingly formed as tubes with a circular cross-section. This has the advantage that the orientation of the attachment of the connector can be chosen freely at an angle to the cross-sectional profile of the channel elements. It is thus possible with the same connector optionally attachment to the wall or the ceiling. The circular cross-section of the inner channel is particularly streamlined and provides the lowest flow resistance.

The connectors are preferably rigid plastic injection molded parts, in particular, their inner wall surface is smooth and free of degrees to ensure a good air flow. On the outer circumference, the connectors may be formed with grooves or undulating in order to ensure a good fit in the channel of the channel elements. Preferably, a seal is arranged on the outer circumference, which causes the fit and the seal of the inner channel to the outside.

The attachment preferably consists of a wall-mountable wall holder and a connector disposed on the fixing. The wall holder is mounted on the wall or ceiling of the room and the connector can then be assembled to assemble the channel elements fixing element with the already mounted wall bracket. A simple assembly is made possible by the fact that the fixing element can be snapped onto the wall holder. When mounting the air duct system, the wall bracket are first attached to the wall or ceiling and the already assembled by means of the connector channel elements are snapped onto the wall holder by means of the fixing elements of the connector. The assembly can be done quickly and easily in this way, with virtually no construction and no reworking are required.

Preferably, the inner channel of the channel elements is formed over its entire axial length with a constant cross section. As a result, the channel elements produced in uniform length can be cut to any length to adapt to the installation dimensions and can be assembled in any length by means of the connector. The sections of the cut-to-length channel elements can be used at another point of the air duct system, so that a cost-effective material-saving installation is possible.

In order to guide the air duct system around corners of the room, corner connectors can be used, which have the shape of a rectangular angled pipe. On the two ends of this corner connector then channel elements are postponed, which are mitred, so that they meet at right angles with a running at 45 ° butt joint together. Alternatively, corner channel elements may be used which have a right angle angled inner channel. At these Eckkanalelemente the straight channel elements can be connected by means of simple connectors.

Further, T-connectors can be used when branches from a channel are required, e.g. B. to guide the air duct from a room through the wall in an adjacent room or to form an opening for the Zuluftauslass or the exhaust air extraction.

In the following the invention will be explained in more detail with reference to embodiments shown in the drawing.

[0016] FIG. <Tb> FIG. 1 <sep> a floor residential unit of a building as an example of the installation of the air duct system, <Tb> FIG. 2 <sep> a channel element in a first embodiment, <Tb> FIG. 3 <sep> a channel element in a second embodiment, <Tb> FIG. 4 <sep> a connector with attachment in the unmounted state, <Tb> FIG. 5 <sep> this connector with the mounting in the assembled state, <Tb> FIG. 6 <sep> a short connector without attachment, <Tb> FIG. 7 <sep> a corner connector in the unmounted state, <Tb> FIG. 8 <sep> this corner connector in the assembled state, <Tb> FIG. 9 <sep> a corner channel element, <Tb> FIG. 10 <sep> a T-connector in the unmounted state, <Tb> FIG. 11 <sep> this T-connector in the assembled state, <Tb> FIG. 12 <sep> a T-channel element, <Tb> FIG. 13 <sep> a wall sleeve, <Tb> FIG. 14 <sep> an end cover, <Tb> FIG. 15 <sep> an aperture for flow adjustment and <Tb> FIG. 16 <sep> a double distribution box.

The inventive air duct system is used in particular for retrofitting existing rooms of a building. Fig. 1 shows an example of the installation of such an air duct system for ventilation of the rooms of a floor residential unit.

A central unit 10 sucks over an outside air line 12 outside air from outside into the building and promotes the exhaust air out of the building via an exhaust air line 14. The sucked outside air is passed from the central unit 10 via a double distributor 24 and a supply air line 16 or star-shaped over several supply air lines in the rooms and exits through air outlets 18 in the rooms. The exhaust air is extracted from the central unit via the double distributor 24 and air openings 22 and conveyed as exhaust air to the outside. The double distributor 24 is preferably designed to be sound-insulating.

The supply air line 16 extends, for example, in the hallway 26 of the residential unit, 16 of these laid in the corridor 26 supply air line 16 stub lines to the air outlets 18 in the inhabited spaces 28, z. B. lead residential and bedrooms. The exhaust air is conveyed via the air openings 22 in the odor and / or moisture-laden rooms 30, e.g. Sucked bath and kitchen. By supplying the supply air into the rooms 28 and the suction of the exhaust air from the rooms 30 creates a slight pressure drop from the rooms 28 to the rooms 30, which counteracts a spread of odor and moisture laden air from the rooms 30. The central device 10 preferably contains a heat exchanger, in which the exhaust air heat can be transmitted to the intake outside air to preheat the supply air.

According to the invention, the air ducts, in particular the supply air line 16, and optionally the outside air duct 12 and the exhaust duct 14 of the air duct system are formed in the manner as shown in FIGS. 2 to 15 and explained below.

The air-carrying lines are formed by channel elements 32, as shown in FIGS. 2 and 3 are shown. The channel elements 32 are axially elongated straight dimensionally stable molded parts made of a foamed plastic, in particular of a closed cell foam and preferably of polystyrene. The channel elements 32 have an axially continuous inner channel 34, which serves for air guidance. The channel 34 may have any cross-sectional shape per se, but preferably the channel 34 is formed with a circular cross-section. The inner channel 34 preferably has a constant constant cross-section over its entire axial length. This results in the advantage that the channel elements 32, which are preferably produced in a uniform length, can be cut to any length to adapt to the installation conditions, the same cross section of the channel 34 always being maintained at the two ends of the channel element 32. The cutting to length of the channel elements 32 is favored in particular by the production of polystyrene, so that the exact length adjustment during installation of the ventilation system can be performed. The production of the inner channel 34 with constant over its entire axial length cross-section can be realized in different ways. For example, the channel 34 may be generated during foaming of the channel elements 32 by means of a folding core. It is also possible to make the channel elements 32 of two half-shells, which are joined along an axially extending, the cross-section of the inner channel 34 bisecting gap 36, as shown in Figs. 2 and 3 shown.

The preparation of the channel elements 32 of a foamed plastic causes a good thermal insulation of the inner channel 34 from the environment. This thermal insulation ensures that the optionally preheated supply air can be passed without cooling to the air outlets 18 of all reamer 28. Likewise, the good thermal insulation prevents condensation of moist room air on the outside of the channel elements 32. The closed-cell foam of the plastic ensures a smooth inner wall of the inner channel 34, so that the channel 34 has a very low air flow resistance, in particular in connection with its round cross-section and also a dirt deposit counteracted. If required, the inner wall of the channel 34 can additionally be treated with an antistatic, antimicrobial or other coating.

The outer lateral surface of the channel elements 32 has two axially continuous planar contact surfaces 38 which abut each other at right angles in an axially continuous edge. With these rectangular contact surfaces 38, the channel elements 32 are inserted into the upper corner of the respective space between the wall and ceiling or possibly also in a vertical corner between two walls. The rectangular arrangement of the flat bearing surfaces 38 ensures a good fit of the channel elements 32 in the existing space. The remaining outer circumferential surface 40 faces the room and thus visible when the channel element 32 is inserted with the contact surfaces 38 in the corner of the room. This outer shell surface 40 can be designed freely to optimally adapt the channel elements 32 and thus the entire air duct system to the room ambience and interior design. The adaptation and thus the design of the outer shell surface 40 can affect both the shape and the surface. 2, an embodiment is shown in which the outer lateral surface is convexly curved and formed in the form of a stucco profile. In the embodiment of FIG. 3, the outer circumferential surface 40 is also formed by two flat rectangular surfaces, so that the channel element 32 has a total of a rectangular or square outer cross section. The surface of the outer surface 40 may be smooth or textured to match the surface of the structure of the wall or ceiling. The outer shell surface 40 can be plastered, painted or papered. It is also possible to dress the outer shell surface 40 with tiles. Thus, an extremely versatile design and an optimal adaptation to the room ambience is possible.

In order to produce an air duct of greater length, the channel elements 32 are joined together without gaps. For this purpose, connectors 42 as shown in Figs. 4 and 5 are shown. The connectors 42 consist of a straight cylindrical tube, which is preferably a rigid plastic injection molded part. The tube cross section corresponds to the cross section of the inner channel 34 of the channel elements 32. If the channel 34 has a circular cross section, the connector 42 accordingly has a circular cross section as well. The outer diameter of the tubular connector 42 corresponds to the inner diameter of the channel 34, so that the connector 42 can be accurately inserted into the channel 34 of the channel member 32. The connector 42 may have grooves at its two axial ends on the outer circumference, resulting in a tight and stable fit of the connector 42 in the channel 34 of the channel member 32. Preferably, a circumferential seal 44 is disposed on the axial ends of the connector 42. The seal 44 is elastic and pushed or sprayed onto the circumference of the connector 42. The seals 44 provide a stable and airtight fit of the connector 42 in the channel 34 of the channel member 32. The wall inner surface of the connector 42 is smooth, so that the connector does not form a flow resistance for the air flowing through.

For axial joining of two channel elements 32, these channel elements 32 are each pushed with their axial ends from the opposite sides of the connector 42. The two channel elements 32 are connected by the fitted connector 42 axially aligned and mechanically stable. Since the connector 42 fits snugly in the respective channels 34, the connector 42 also connects the inner channels 34 of the adjoining channel elements 32 and seals the axial butt joint between these channel elements 32 to the outside.

To secure the channel members 32 to the wall or ceiling of the room, the connectors 42 are provided with a fixture by which the connectors 42 can be secured to the wall or ceiling. The wall or ceiling mounted connectors 42 thereby cantilevered to hold the connectors 42 plugged channel members 32, without these channel elements 32 need any own attachment.

The attachment of the connector 42 consists of a wall holder 46 which is fixed to the wall of the room or preferably to the ceiling of the room and a fixing member 48 which is arranged on the connector 42. In the embodiment shown in the drawing, the wall holder 46 is preferably made as a plastic injection molded part. It has a base plate 50 with openings 52. The base plate 50 is applied to the wall or ceiling of the room and secured by means of the apertures 52 sweeping screws on the wall or ceiling. The openings 52 are in particular formed as slots in order to allow an adjustment of the base plate 50 in the plane of the wall or ceiling. On the base plate 50 two locking tongues 54 are formed, which project perpendicularly from the base plate 50 and are arranged parallel to each other and spaced from each other. On the mutually facing surfaces of the locking tongues 54 latch grooves 56 are formed, which extend parallel to the plane of the base plate 50. The base plate 50 is extended beyond one of the locking tongues 54, this extension forming a spacer 58. The fixing 48 are formed as two mutually surface-parallel locking plates which are spaced from each other parallel to the central axis of the connector 42 and preferably integrally molded to the connector 42. The distance between the fixing elements 48 is matched to the mutual distance of the locking tongues 54, that the fixing elements 48 can engage between the locking tongues 54 of the wall holder 46, wherein the opposite outer surfaces of the fixing elements 48 abut the mutually facing inner surfaces of the locking tongues 54. The fixing elements 48 have locking grooves 60 on their outer sides facing away from each other, which correspond to the latching grooves 56 of the latching tongues 54 and come into engagement therewith. If the connector 42 is inserted with its fixing elements 48 in the locking tongues 54 of the wall holder 46, it can be locked by means of the interlocking locking grooves 56 of the locking tongues 54 and the locking grooves 60 of the fixing elements 48 with adjustable distance of its central axis of the base plate 50 of the wall bracket 46 become. The interlocking locking grooves 56 and 60 hold the connector 42 while in the respective detent position. The width of the fixing elements 48 in the axial direction of the connector 42 and thus the length of the locking grooves 60 is greater than the width of the locking tongues 54 and thus the length of the locking grooves 56. The latched connector 42 can thereby be displaced and adjusted in its axial direction by the fixing elements 48 are moved relative to the locking tongues 54, wherein the locking grooves 56 and 60 slide into one another.

For mounting the connector 42, the wall holder 46 are first attached to the wall or the ceiling of the room. The spacers 58 are used here, the base plate 50 in a well-defined distance from the wall (when mounting the wall bracket 46 on the ceiling) or from the ceiling (when mounting the wall bracket 46 on the wall) to install. This distance is such that the connector 42 secured to the wall bracket 46 holds the plugged channel members 32 against the wall or ceiling. The adjoining channel elements 32 are plugged onto the connector 42 from the two ends. Now, the connector 42 is locked together with the channel elements 32 carried by him in the mounted wall holder 46 by means of the fixing elements 48. The engagement of the fixing elements 48 by means of the latching grooves 60 in the latching tongues 54 and their latching grooves 56 allows adaptation and adjustment of the distance of the connector 42 from the wall or ceiling to which the wall bracket 46 is mounted. The second contact surface 38 of the channel elements 32 can thus be brought into exact contact with the wall or ceiling. An adjustment in the axial direction is possible by displacement of the connector 42 by means of the locking grooves 60 in the locking grooves 56 of the notches 54. Fig. 4 shows the wall bracket 46 and the connector 42 separated, while Fig. 5 shows the assembled state in which the connector 42 with its fixing members 48 is engaged in the wall bracket 46.

The adjoining each channel elements 32 can each be pushed axially as far as the connector 42 that their end faces closely and seamlessly abut each other. So that this gapless joining is not hindered by the wall holder 46 and the fixing elements 48, the channel elements 32 have a cutout 62 on their end face. By this cutout 62, this axial end face of the channel member 32 is set back in the region of the contact surfaces 38 with respect to the axial end face in the region of the outer shell surface 40. The cutout 62 allows in this way that the aneinanderanzuschlendes channel elements 32 in the region of their outer shell surface 40 directly and completely against each other while the wall holder 46 and the fixing elements 48 are received in the cutout 62. It is thereby achieved that the mutually joined channel elements 32 completely cover the connectors 42 and their attachment to the wall or the ceiling with the outer jacket surfaces 40 visible from the space and make them invisible from the room side. Since the connectors 42 are snapped with their fixing elements 48 only in the previously fixed wall bracket 46, the attachment during installation of patch on the connector 42 channel elements 32 must not be accessible from the outside.

If a supporting attachment of the channel elements to the ceiling or wall is not necessary, e.g. for short channel elements, a short connector 80 as shown in FIG. 6 may be used. The short connector 80 corresponds in tube form to the connector 42, but has no fixing elements and consequently a smaller axial length. On the short connector 80 each channel elements 32 can be pushed from both sides. An outer stop collar 82 integrally formed axially on the short connector 80 serves for the axial positioning of the short connector 80 in the channel elements 32.

By the axially aligned joining together of the straight channel elements 32 through the connector 42, as shown in FIGS. 4 and 5, straight air ducts of any length of channel elements 32 of a predetermined uniform length can be formed. To adapt to specific length dimensions, the channel elements 32 can be cut to length. If the air guidance system is to be guided around a corner of the room, different developments of the invention are possible, as illustrated, for example, in FIGS. 7 to 9.

In one embodiment, which is shown in Figs. 7 and 8, a corner connector 64 is used to connect the adjoining each other in a corner of the room channel elements 32. The corner connector 64 results in its shape by two connectors 42 of the form shown in Fig. 4 and 5 are set with an axial end at 90 ° to each other. The extending at 90 ° ends of the corner connector 64 correspond with its seal 44 and consisting of wall holder 46 and fixing elements 48 attachment of the above-described embodiment of Figs. 4 and 5, to which reference is made.

On the lower than 90 ° to each other extending ends of the corner connector 64 straight channel elements 32 are plugged, wherein the pushed onto the corner connector 64 ends of the channel elements 32 are cut at 45 ° miter so that they butt together with their ends together and the corner connector 64 completely cover with its fixings against view from the room side.

An alternative embodiment is shown in FIG. 9. In this embodiment, a separate Eckkanalelement 66 is provided, which is made according to the channel member 32 as a rigid molded part of a foamed plastic. The cube-shaped Eckkanalelement 66 has an upper planar contact surface 38 which bears against the ceiling and two at 90 ° to each other and against the upper contact surface angled abutment surface 38, which bear against the walls. The end faces of the corner channel element 66 are thereby at a right angle to each other. The inner channel 34 extends in the Eckkanalelement 66 at a right angle. Straight channel elements 32 of FIGS. 2 and 3 can each be connected by means of a connector 42 of FIGS. 4 and 5 to the end faces of the corner channel element 66 that are at right angles to one another. The Eckkanalelement 66 is supported by the fasteners of the two connectors 42. The fasteners are received by the cutout 62 of the subsequent channel elements 32. Likewise, it is possible to connect channel elements 32 by means of short connectors according to FIG. 6 to the corner channel element 66.

The Eckkanalelement 66 can be used in an inner corner of the room. Likewise, corner channel 66 may be used to route the air duct around an outside corner of the room.

If a branch from the air duct is required in the air ducting system, e.g. To direct the air from a room through the building wall into an adjacent space or to form an air outlet 18, the embodiments of the invention shown in Figs. 10 and 11 and 6 and 12 are used.

Figures 10 and 11 show a T-connector 68 which serves to make a branch of the air-conducting duct. The T-connector 68 corresponds in its basic construction to the connector 42 of Figs. 4 and 5, so that reference is made to the description there. Unlike the connector 42, the T-connector 68 has a right-angled branch 70 in the axial center of the tubular connector which has the same tube cross-section and is also provided with a seal 44. On the two axial ends of the T-connector 68 channel elements 32 can be placed in the manner described above. The axially abutting ends of these channel elements 32 have in addition to the cutout 62 for the attachment a cutout for the branch 70 on. On the branch 70, an air outlet 18 can be placed. Likewise, the air-conducting channel can be guided via the branch 70 into an adjacent room.

An alternative for a branch is shown in FIG. 12. In this embodiment, a T-channel element 74 is used. The T-channel element 74 is a dimensionally stable molded part made of foamed plastic, which essentially corresponds to the straight channel element 32. In contrast to this, the T-channel element 74 has in its axially central region a branch channel 76, which opens into the inner channel 34 at right angles, has the same inner cross-section and emerges perpendicularly from one of the contact surfaces 38. The T-channel element may be connected to straight channel elements 32 in the manner described above by means of connectors 42 or short connectors 80. In the branch channel 76, for example, an air outlet 18 can be used.

If the branch of the channel lead through a room wall, it can be connected to the branch channel 76, a wall sleeve 72, as shown in Fig. 13shows. The wall sleeve 72 has the same inner diameter as the branch channel 76 and is mated with this by means of a short connector 80. The axial length of the wall sleeve 72 corresponds to the strength of the room wall. At the opposite end of the wall sleeve 72, which exits the wall in the adjacent room, in turn, an air outlet 18 or the like can be placed. Likewise, by means of a short connector 80, a channel element 32 or a T-channel element 74 can be connected in order to continue the air-conducting channel in the adjacent room.

In order to close off the end of the air guidance system, an end cover 78 shown in FIG. 14 can be used. This end cover 78 is a plastic molding. The end cap 78 is used to close the inner channel 34 in the free end of the channel member 32. For optical closure of the free end of the last channel element 32, this butt can butt against a room wall. If the channel element 32 does not terminate at the end of the room, a corner channel element 66 according to FIG. 9 can be added to the free end of the last channel element 32 by means of a short connector 80, the open end of the inner channel 34 being directed against the wall or ceiling of the room and thus is invisible.

In order to adapt the air flow in the individual branches of the air guidance system to a different supply air requirement in different rooms, volume holes 84 can be used in the inner channels 34 of the channel elements 32, 66, 74 or in the wall sleeve 72, as shown by way of example in FIG are shown. The volume orifice 84 is a short tubular plastic part which is fitted with seals 44 in the inner channel 34. The inner cross section of the volume hole stop 84 is partially closed by concentric circular disks 86. By breaking out these circular disks 86, the free passage cross section of the volume-perforated diaphragm 84 can be adapted to the respective supply of fresh air.

Fig. 16 shows an embodiment of the double distributor 24. The double distributor 24 consists of a cuboid housing 88, which is preferably lined sound-absorbing. The connection 92 for supply air coming from the central device 10 and the connection 94 for the exhaust air extracted from the central device 10 open into an end wall 90. The supply air is passed through the inner volume of the housing 88 to a Zuluftauslass 96 in the opposite end wall. At this Zuluftauslass 96, the supply air line 16 is connected by z. B. by means of a short connector 80, a channel element 32 is connected. In the two side walls of the housing 88 open respectively exhaust ports 98, which are cased inside the housing 88 to the port 94. The exhaust openings 98 open directly into one of the spaces 30 or via a wall sleeve 72 in an adjacent space 30. The housing 88 also has a closable by a cover 100 inspection opening.

LIST OF REFERENCE NUMBERS

[0043] <Tb> 10 <sep> central unit <Tb> 12 <sep> outside air line <Tb> 14 <sep> exhaust air line <Tb> 16 <sep> Supply line <Tb> 18 <sep> outlets <Tb> 22 <sep> air openings <Tb> 24 <sep> Double distributor <Tb> 26 <sep> corridor <tb> 28 <sep> inhabited rooms <tb> 30 <sep> charged rooms <Tb> 32 <sep> channel elements <tb> 34 <sep> inner channel <Tb> 36 <sep> fugue <Tb> 38 <sep> contact surfaces <Tb> 40 <sep> outer casing surface <Tb> 42 <sep> connector <Tb> 44 <sep> seal <Tb> 46 <sep> Wall mount <Tb> 48 <sep> fixing <Tb> 50 <sep> base <Tb> 52 <sep> Breakthrough <Tb> 54 <sep> locking tongues <Tb> 56 <sep> Rest grooves <Tb> 58 <sep> Spacers <Tb> 60 <sep> Rest grooves <Tb> 62 <sep> cutout <Tb> 64 <sep> corner connector <Tb> 66 <sep> Eckkanalelement <Tb> 68 <sep> T-connector <Tb> 70 <sep> branch <Tb> 72 <sep> Wall sleeve <Tb> 74 <sep> T channel element <Tb> 76 <sep> branch channel <Tb> 78 <sep> End Cap <Tb> 80 <sep> short connector <Tb> 82 <sep> stop collar <Tb> 84 <sep> volume pinhole <Tb> 86 <sep> annular disks <Tb> 88 <sep> Housing <Tb> 90 <sep> bulkhead <tb> 92 <sep> Connection for supply air <tb> 94 <sep> Connection for exhaust air <Tb> 96 <sep> Supply air <Tb> 98 <sep> exhaust vents <Tb> 100 <sep> Lid

Claims (27)

An air duct system for ventilating rooms of a building with channel elements (32) for air guidance, with connectors (42) for connecting the channel elements (32) to each other, with fasteners (46, 48) for mounting the air duct system in the room, the channel elements (32 ) have an axially continuous inner channel (34), wherein the connectors (42) are rigidly tubular and at the ends of the channel elements (32) fitting in the channel (34) can be inserted, wherein the connectors (42) by means of attachment ( 46, 48) are mountable on a wall or ceiling of the room and wherein in the assembled state of the system two channel elements (32) plugged onto a connector (42) are carried by this connector (42), characterized in that the channel elements (32 ) are elongated straight dimensionally stable moldings made of foamed plastic, that the outer lateral surface of the channel elements (32) has two planar contact surfaces (38), in an axi abut the extending edge at right angles, that the two channel elements (32) plugged onto a connector (42) abut each other axially with their ends and cover the connector (42) and its attachment (46, 48) from the outside as viewed by the channel elements (32). 32) at at least one end face have a cutout (62) which is open to the abutment surfaces (38) and receives at axially abutting channel elements (32) the attachment (46, 48) of the connector (42). 2. Air duct system according to claim 1, characterized in that the inner channel (34) and the connector (42) have a circular cross-section. 3. Air duct system according to claim 1 or 2, characterized in that the channel (34) has a over the entire axial length of the channel member (32) continuously constant cross-section. 4. Air duct system according to one of claims 1 to 3, characterized in that the inner wall of the channel (34) is formed smooth and closed cell. 5. Air duct system according to claim 4, characterized in that the inner wall of the channel (34) is provided with an anti-electrostatic, anitmikrobiellen or other coating. 6. Air duct system according to one of the preceding claims, characterized in that the channel elements (32) consist of foamed polystyrene. 7. Air duct system according to claim 3, characterized in that the inner channel (34) is made by a folding core. 8. Air duct system according to claim 3, characterized in that the channel elements (32) are made bivalve and along a the inner channel (34) dividing joint (36) are joined together. 9. Air duct system according to one of the preceding claims, characterized in that the outer lateral surface (40) of the channel elements (32) outside the contact surfaces (38) is formed with smooth or textured surface, in the form of a Stuckprofils or with flat surfaces and / or cleanable, can be painted or wallpapered. 10. Air duct system according to one of the preceding claims, characterized in that the connectors (42) are dimensionally stable rigid plastic injection molded parts. 11. Air duct system according to claim 10, characterized in that the inner wall of the connector (42) is smooth and burr-free. 12. Air duct system according to one of the preceding claims, characterized in that the connectors (42) have at their ends on their outer shell a seal (44) for anchoring and sealing in the channel (34) of the channel elements (32). 13. Air duct system according to one of the preceding claims, characterized in that the attachment has a mountable on the wall or ceiling of the room wall holder (46) and on the connector (42) fixing elements (48) and that the wall holder (46) and the Fixing elements (48) for mounting the air duct system to the wall or ceiling are joined together. 14. Air duct system according to claim 13, characterized in that the fixing elements (48) on the wall holder (46) can be latched. 15. Air duct system according to claim 13 or 14, characterized in that the connectors (42) by means of the wall holder (46) and the fixing elements (48) in three axes with respect to the wall or ceiling of the room are adjustable. 16. Air duct system according to claim 15, characterized in that the wall holder (46) on the ceiling or wall in the plane of the ceiling or wall are adjustable fastened. 17. Air ducting system according to claim 15, characterized in that the fixing elements (48) in an adjustable distance from the wall or ceiling in the wall holder (46) can be latched. 18. Air guiding system according to one of claims 15 to 17, characterized in that the fixing elements (48) in the wall brackets by means of latching grooves (56, 60) can be latched, the displacement of the fixing elements (48) relative to the wall holder (46) axially parallel to the Allow connector (42). 19. Air duct system according to one of claims 1 to 18, characterized in that short connectors (80) are provided in the form of short pieces of pipe, which allow a joining of the channel elements (32) without attachment. 20. Air duct system according to one of claims 1 to 19, characterized in that in addition corner connectors (64) are provided on which channel elements (32) are attachable at right angles to each other, wherein the channel elements (32) abut one another with a miter cut. 21. Air duct system according to one of claims 1 to 19, characterized in that in addition Eckkanalelemente (66) are provided which have mutually perpendicular end faces, the inner channel (34) extends at right angles and other end faces channel elements (32) by means of connectors (42) or short connectors (80) can be added. 22. Air duct system according to one of claims 1 to 21, characterized in that in addition T-connector (68) are provided which have a right-angled branch (70) between their axial ends. 23. Air duct system according to one of claims 1 to 21, characterized in that in addition T-channel elements (74) are provided which have a right angle in the inner channel (34) opening branch channel (46) which on one of the abutment surfaces (38) exit. 24. Air duct system according to claim 22 or 23, characterized in that at the branch (70) and the branch channel (76) has a wall sleeve (72) is connectable. 25. Air duct system according to one of the preceding claims, characterized in that the free end of a channel element (32) by a cube-shaped Eckkanalelement (66) is lockable. 26. Air duct system according to one of the preceding claims, characterized in that in the inner channel (34) of the channel elements (32) volume holes (84) can be used. 27. Air duct system according to one of the preceding claims, characterized in that a double distributor (24) directs the supply air from a central device (10) into a channel elements (32) constructed supply air line (16) and the exhaust air to the central device (10). passes.