EP3837474A1 - Ventilation system - Google Patents

Abstract

The invention relates to a ventilation system (10) for at least one space (100), comprising at least one ventilation device (20) with at least one housing (30) which has a first flow duct (40) with, arranged therein, at least one fan (44) for delivering outside air into the space (100) and at least one second flow duct (50) with, arranged therein, at least one fan (54) for delivering exhaust air from the space (100), wherein at least one respective section (46; 56) of the first flow duct (40) and the second flow duct (50) runs in the region of a heat exchanger (60). In order to provide an improved ventilation system with high efficiency, maintainability and adaptability to different installation situations, it is provided according to the invention that the housing (30) of the ventilation device (20) is divided in modular fashion into at least three housing portions (31; 32; 33) by means of at least two partition walls or partition surfaces (35; 36) that are arranged essentially perpendicular to the main flow direction of the outside air and exhaust air. At least one of the fans (44; 54) is arranged, for noise minimizing purposes, on that side of the flow ducts (40; 50) that is oriented away from the space (100).

Description

Ventilation system

The invention relates to a ventilation system for a room according to the preamble of claim 1. When a ventilation system is spoken of in this application, it always means a ventilation system by means of which both outside air as supply air into a room and exhaust air as exhaust air can be transported in one room.

A generic ventilation system is known from EP 2 850 273 B1. In this known ventilation system, a ventilation device for docking to a frame of a window or door is described, in which two flow channels each provided with a fan are guided over a heat exchanger in such a way that heat is transferred between the exhaust air sucked in from the inside of the room to the outside outside air sucked into the room is made possible.

The object of the invention is to create an improved ventilation system with a high level of efficiency, ease of maintenance and adaptability to different installation situations.

This object is achieved by a ventilation system with the features of claim 1. Advantageous refinements of the invention are specified in the related subclaims.

The ventilation system according to the invention is characterized by a high degree of modularity of the ventilation device, which enables simple installation, simple maintenance and simple, tool-free and non-destructive replacement of

Components enables. It stands out over the prior art characterized in that the ventilation device forming a core of the ventilation system has at least three housing sections divided essentially transversely to the main flow direction of the air in the flow channels.

The ventilation system according to the invention thus enables, for example, a simple removal and installation or replacement of filters, fans or blowers, a heat exchanger or other components. Removal and installation can be done for maintenance or repair purposes or to bring the ventilation system up to date with the latest technical developments by upgrading individual components.

Furthermore, the ventilation system according to the invention is characterized by a great variability of the installation and connection options, which can be found in the

reflects numerous embodiments shown in the figures.

In the ventilation system according to the invention, at least one of the blowers or fans for conveying the outside air and / or the exhaust air is on the

Interior side facing away from the flow channels arranged. In this way, the sound emanating from the fans is effectively attenuated by means of other parts of the ventilation device located between the fans and the interior. In addition, at least one silencer can optionally be arranged in at least one of the flow channels, which silencer ensures further attenuation of the sound transmitted to the interior.

The ventilation system according to the invention particularly preferably has a preheating and / or cooling register in the first flow channel near an outside air inlet. This enables year-round continuous operation regardless of the temperature and / or the humidity of the outside air, the heat exchanger being automatically balanced and always kept frost-free.

The heat exchanger used in the ventilation system according to the invention is preferably designed as an enthalpy heat exchanger. This eliminates the problem of condensate discharge in the ventilation system according to the invention. In a In a particularly advantageous embodiment, it is provided that the flow channels with their sections assigned to the heat exchanger in one

Countercurrent arrangement are arranged. Overall, this increases the efficiency in such a way that around 85% of the thermal energy in the exhaust air can be transferred to the outside air.

In an advantageous embodiment it is provided that at least one filter is arranged in the first flow channel and / or in the second flow channel near the inlet of the outside air or the exhaust air. The filtering of the outside air and the exhaust air ensures that the ventilation system in the area of the

Heat exchanger or the fan is effectively protected from contamination.

In addition, only cleaned outside air is fed into the interior through the filter. Due to the modular design of the ventilation unit, the filters are also very easy to replace or clean.

In a further advantageous embodiment it is provided that an electronic control for the ventilation device is arranged in one of the housing sections. The coupling of the signal lines and the power lines between the electronic control and the electrical components, such as the fans, is preferably carried out automatically when the modules are inserted into the housing sections, for example by means of spring loaded contacts. Alternatively, the coupling of the electrical lines can also be established by plug connections, the voltage-carrying contacts of which are used when the electrical components are dismantled

are designed to be safe to touch.

The electronic control is preferably in signal connection with a control device which is optionally arranged on the inside of the ventilation device facing the interior space or is wirelessly designed as a remote control. As an alternative or in addition to this, it is possible to integrate the control device - either wirelessly (e.g. via Bluetooth® or WLAN) or wired (via a LAN connection) - into a house network, so that the ventilation system can also be used as a module within a more comprehensive SmartHome control, for example using their remote control and / or an app on a smartphone

controllable, can be used.

In a further advantageous embodiment of the invention

The system provides that at least one photovoltaic module and an accumulator for storing the energy for the ventilation device are arranged in at least one of the housing sections. The generation and storage of the electrical energy required for the blower integrated into the ventilation system enables the ventilation system to operate completely independently, which means

especially in the case of retrofitting solutions in old buildings to an expensive one

Cabling can be dispensed with.

According to a first advantageous embodiment of the system according to the invention it is provided that at least one ventilation device of the ventilation system is arranged on a reveal of a window or on the inside of a wall delimiting the room or in an opening in the wall in such a way that the

Housing sections are positioned vertically one above the other. The vertical arrangement, in conjunction with the horizontal partition walls dividing the three housing sections, enables a simple drawer-like insertion or pulling out of individual housing sections for maintenance or replacement of the components of the ventilation system accommodated by these.

Thus, in the upper housing section, a fan for conveying outside air, a filter arranged near the exhaust air inlet and a near the

Exhaust air inlet arranged silencer by pulling out the upper one

Housing part can be made easily accessible for maintenance or replacement. Pulling out the middle housing part also makes the heat exchanger easily accessible. A fan for conveying the exhaust air or exhaust air can be made easily accessible by pulling out the lower housing part.

According to a particularly advantageous further development of the system according to the invention, it is provided that at an inlet for the outside air and / or an inlet for the exhaust air and / or at an outlet for the supply air and / or at an outlet for the exhaust air on at least one of the flow channels a Channel for deflecting the air and / or for conveying the air into or from an adjacent room can be arranged. This results in a high degree of flexibility in the installation of the ventilation system according to the invention, both in the case of retrofitting solutions (for example replacing windows in old buildings) and in the case of

Given new buildings. By means of the ducts, the outside air and / or the exhaust air can either be sucked in or discharged parallel or perpendicular to the window or the wall. The ducts can also be connected to an adjacent interior via openings through a wall delimiting the interior space or via air ducts arranged in a ceiling and / or in the floor of the room

be connected and thereby ensure an exchange of air there too. Such an arrangement is particularly useful and inexpensive for windowless side rooms, toilets or bathrooms, in which their ventilation takes place via a window or a wall of an adjacent room.

In the following, exemplary embodiments of the system according to the invention are explained in more detail with reference to the drawings. It shows:

1 shows a schematic longitudinal section of one in a wall or next to one

Window reveal of built-in ventilation device,

2A shows a schematic view of a ventilation device installed on a right reveal of a window with a direct outside air inlet, supply air outlet, exhaust air inlet and exhaust air outlet,

Fig. 2B shows a cross section through Fig. 2A,

3A shows a schematic view of a ventilation device installed on a left reveal of a window with a direct outside air inlet, supply air outlet, exhaust air inlet and exhaust air outlet,

Fig. 3B shows a cross section through Fig. 3A,

4A shows a schematic view of one in a wall opening on the right

Ventilation unit built into the window with a direct outside air inlet, supply air outlet, exhaust air inlet and exhaust air outlet,

FIG. 4B shows a cross section through FIG. 4A, 5A shows a schematic view of one in a wall opening on the left

Ventilation unit built into the window with a direct outside air inlet, supply air outlet, exhaust air inlet and exhaust air outlet,

FIG. 5B shows a cross section through FIG. 5A,

6A shows a schematic view of a ventilation device installed on a right reveal of a window with outside air being drawn in parallel to the pane of the window and the exhaust air being conveyed away and with a direct supply air inlet and outlet air;

6B shows a cross section through FIG. 6A,

7A shows a schematic view of a ventilation device installed on a left reveal of a window with outside air being drawn in parallel to the pane of the window and the exhaust air being conveyed away and with a direct supply air inlet and outlet air;

7B shows a cross section through FIG. 7A,

8A is a schematic view of a ventilation device arranged on a right side of a window on the wall of the room with a suction of the outside air and removal of the exhaust air taking place parallel to the pane of the window via ducts introduced into the wall and with a direct supply air inlet and outlet,

FIG. 8B shows a cross section through FIG. 8A,

9A is a schematic view of a ventilation device arranged on a left side of a window on the wall of the room with a suction of the outside air and removal of the exhaust air taking place via ducts introduced into the wall parallel to the pane of the window and with a direct supply air inlet and exhaust air outlet,

FIG. 9B shows a cross section through FIG. 9A,

10A shows a schematic view of a ventilation device installed on a right reveal of a window with ducts arranged parallel to the inner wall of the room for venting an adjacent room,

FIG. 10B shows a cross section through FIG. 10A,

11A shows a schematic view of a ventilation device installed on a left reveal of a window with ducts arranged parallel to the inner wall of the room for venting an adjacent room, FIG. 11 B shows a cross section through FIG. 11 A,

12A is a schematic view of one adjacent to a right side of one

Window on the wall of the room with ventilation device arranged parallel to the inside wall of the room for ventilating an adjacent room and with ducts built into the wall for sucking in outside air and conveying away the exhaust air,

FIG. 12B shows a cross section through FIG. 12A,

13A shows a schematic view of a ventilation device arranged next to a left side of a window on the wall of the room with channels arranged parallel to the inner wall of the room for venting an adjacent room and with channels made in the wall for drawing in outside air and conveying away the exhaust air,

13B shows a cross section through FIG. 13A,

14A is a schematic view of a ventilation device installed on a right reveal of a window with ducts arranged parallel to the inner wall of the room for ventilating an adjacent room and with outside air being drawn in parallel to the pane of the window and the exhaust air being conveyed away,

14B shows a cross section through FIG. 14A,

15A shows a schematic view of a ventilation device installed on a left reveal of a window with ducts arranged parallel to the inner wall of the room for venting an adjacent room and with outside air being drawn in parallel to the pane of the window and the exhaust air being conveyed away,

Fig. 15B shows a cross section through Fig. 15A,

16A is a schematic view of one adjacent to a right side of one

Window on the wall of the room with ventilation device arranged parallel to the inner wall of the room for ventilating an adjacent room and with ducts made in the wall for drawing in outside air and conveying the exhaust air parallel to the pane of the window,

FIG. 16B shows a cross section through FIG. 16A, 17A is a schematic view of a ventilation device arranged next to a left side of a window on the wall of the room with ducts arranged parallel to the inner wall of the room for venting an adjacent room and with ducts made in the wall for sucking in outside air and conveying away the exhaust air parallel to the Pane of window,

FIG. 17B shows a cross section through FIG. 17A,

18A shows a schematic view of a ventilation device installed on a right reveal of a window with ducts arranged parallel to the inner wall of the room for ventilation of an adjacent room and with outside air being sucked in perpendicular to the pane of the window and the exhaust air being conveyed away,

FIG. 18B shows a cross section through FIG. 18A,

19A shows a schematic view of a ventilation device installed on a left reveal of a window with ducts arranged parallel to the inner wall of the room for ventilation of an adjacent room and with outside air being sucked in perpendicular to the pane of the window and the exhaust air being conveyed away,

19B shows a cross section through FIG. 19A,

20A is a schematic view of one adjacent to a right side of one

Window on the wall of the room with ventilation device arranged parallel to the inner wall of the room for ventilation of an adjacent room and with channels built into the wall for sucking in the outside air and conveying the exhaust air perpendicular to the pane of the window,

FIG. 20B shows a cross section through FIG. 20A,

21A is a schematic view of a ventilation device arranged next to a left side of a window on the wall of the room with ducts arranged parallel to the inner wall of the room for ventilation of an adjacent room and with ducts made in the wall for sucking in outside air and conveying away the exhaust air vertically to the pane of the window,

FIG. 21 B shows a cross section through FIG. 21 A, 22A is a schematic view of a ventilation device installed on a right reveal of a window with ducts arranged parallel to the inner wall of the room for ventilation of an adjacent room and with outside air being drawn in and exhaust air being conveyed parallel to the pane of the window,

FIG. 22B shows a cross section through FIG. 22A,

23A shows a schematic view of a ventilation device installed on a left reveal of a window with ducts arranged parallel to the inner wall of the room for ventilating an adjacent room and with outside air being drawn in and exhaust air conveyed parallel to the pane of the window,

23B shows a cross section through FIG. 23A,

24A is a schematic view of one adjacent to a right side of one

Window ventilation device arranged on the wall of the room with ducts arranged parallel to the inner wall of the room for ventilation of an adjacent room and with ducts made in the wall for drawing in outside air and conveying away the exhaust air parallel to the pane of the window,

FIG. 24B shows a cross section through FIG. 24A,

25A is a schematic view of a ventilation device arranged next to a left side of a window on the wall of the room with channels arranged parallel to the inner wall of the room for ventilation of an adjacent room and with channels introduced into the wall for sucking in outside air and conveying away the exhaust air parallel to the Pane of window,

25B shows a cross section through FIG. 25A,

26A is a schematic view of one adjacent to a right side of one

Ventilation device arranged in the window soffit with intake of outside air and removal of exhaust air perpendicular to the pane of the window and ventilation of an adjacent room through a duct in the ceiling of the room,

FIG. 26B shows a cross section through FIG. 26A, 27A is a schematic view of a ventilation device arranged next to a left-hand side of a window in the reveal with intake of outside air and removal of exhaust air perpendicular to the pane of the window and ventilation of an adjacent room through a duct arranged in the ceiling of the room,

FIG. 27B shows a cross section through FIG. 27A,

28A is a schematic view of one adjacent to a right side of one

Window ventilation device arranged on the wall of the room with intake of outside air and discharge of exhaust air perpendicular to the pane of the window and ventilation of an adjacent room through a duct in the ceiling of the room,

FIG. 28B shows a cross section through FIG. 28A,

29A is a schematic view of a ventilation device arranged next to a left side of a window on the wall of the room, with intake of outside air and removal of exhaust air perpendicular to the pane of the window and ventilation of an adjacent room through a duct arranged in the ceiling of the room ,

29B shows a cross section through FIG. 29A,

30A is a schematic view of one adjacent to a right side of one

Ventilation device arranged in a window soffit with intake of outside air and removal of exhaust air parallel to the pane of the window and ventilation of an adjacent room through a duct in the ceiling of the room,

FIG. 30B shows a cross section through FIG. 30A,

31 A is a schematic view of a ventilation device arranged next to a left side of a window in a reveal with suction of outside air and removal of exhaust air parallel to the pane of the window and ventilation of an adjacent room through a duct arranged in the ceiling of the room,

Fig. 31 B shows a cross section through Fig. 31 A,

32A is a schematic view of one adjacent to a right side of one

Ventilation device arranged on the wall of the room with a suction of the outside air and a discharge of the exhaust air parallel to the window The pane of the window through ducts made in the wall and ventilation of an adjacent room through a duct located in the ceiling of the room,

FIG. 32B shows a cross section through FIG. 32A,

33A is a schematic view of a ventilation device arranged next to a left-hand side of a window on the wall of the room with intake of outside air and removal of exhaust air parallel to the pane of the window via ducts made in the wall and ventilation of an adjacent room through an in duct placed on the ceiling of the room,

33B shows a cross section through FIGS. 33A, and

34 is a schematic view of an empty one for plastering into a

Wall opening or housing of a ventilation device suitable on a reveal before the modular components are installed in the housing and before the ventilation device is installed in a wall or a reveal.

In FIG. 1, a ventilation system 10 according to the invention with a ventilation device 20 built into a wall 120 is shown in cross section. Instead of in a wall 120, the ventilation device 20 can also be arranged on a reveal 112 of a window 110, as shown in FIGS. 2 and 3 and numerous other figures in the following. The ventilation device 20 is preferably adapted to the height of the window 110. If the window 110 extends down to a floor 102 of a room 100 (see FIGS. 2 and 3) and / or up to a ceiling 104 of the room 100, a housing 30 of the ventilation device 20 is preferably at the height of the window 110 adapted, wherein the compensation of the additional height can also be generated by filling modules, not shown, arranged below and / or above the housing 30 and adapted in cross section to the ventilation device 20.

According to the exemplary embodiment shown in FIG. 1, the ventilation device 20 has a housing 30 with three housing sections 31, 32 and 33 arranged vertically one above the other. The housing 30 is upward through a horizontal upper Housing wall 34 and delimited at the bottom by a horizontal lower housing wall 37. Between the upper housing wall 34 and the lower housing wall 37, two further horizontally extending partition walls 35 and 36 are provided, by means of which the housing sections 31 and 32 or 32 and 33 are separated from one another. Instead of the partition walls 35, 36, the housing sections 31, 32 and 33 can also be subdivided by bottom parts of slide-in modules arranged at the same height and acting as separating surfaces 35, 36, which can be pushed into the housing 30 with holders arranged at a corresponding height. The partition walls 35, 36 or the slide-in modules are preferably provided with seals which, when inserted into the housing 30, seal against the adjacent modules or the partition walls 35, 36, so that between the housing sections 31, 32 and 33 vertically Direction always prefers one

flow-tight sealing takes place.

The housing 30 is delimited at the front towards an outer area 200 by an outer wall. The outer wall is in the area of the first

Housing section 31 is designated with 312, in the area of the second housing section 32 with 322 and in the area of the third housing area 33 with 332. The housing 30 thus forms a rack that is open towards an interior 100, into which the three individual modules of the ventilation device 20 in the exemplary embodiment shown can be inserted and removed from the interior 100. The housing 30 is also shown in the unequipped state in FIG. 34 and will be described in detail further below.

In the first housing section 31, the outer wall 312 has an outside air inlet 41 of a first flow channel 40 in the upper region. In this first one

Flow channel 40, which after the horizontal entry of the outside air continues angled downwards in the area of the outside air inlet 41, are shown in FIG

A filter 42 and a preheating or cooling register 43 are arranged one after the other in the direction of flow. This is followed by a fan 44 in the direction of flow. The filter 42 is designed, for example, as a filter of filter class F7 in accordance with DIN EN 779. The outside air then enters the second housing section 32 through an opening 3545 in the partition 35 and continues downward there in a section 45 of the first flow channel 40. In the second housing section 32, a heat exchanger 60 designed as an enthalpy heat exchanger is arranged, through which the first flow channel 40 with its section 45 running vertically downwards past the heat exchanger 60 obliquely upwards

angled section 46 runs. After reaching the top of the

Heat exchanger 60, the first flow channel 40 goes downwards with a section 47 which is angled vertically downwards and runs past the heat exchanger 60 near an inner wall of the housing 30. The section 47 of the first flow channel then passes through an opening 3647 in the partition wall 36 into the third housing section 33, where it opens horizontally at an angle and / or vertically downwards to the interior 100 with at least one

Outside air outlet 48 in this.

On the inside facing the interior 100, the first

Housing section 31 has a horizontally extending exhaust air inlet 51 in the upper area. The exhaust air inlet 51 forms the beginning of a second flow channel 50. This is passed with a vertically downward section 55 first over a filter 52 and then over a silencer 53. The filter 52 is designed, for example, as a filter of filter class F7 in accordance with DIN EN 779.

Alternatively, the filter 52 can also be formed by an easy-to-clean filter network. Subsequent to the silencer 53, the section 55 of the second flow channel 50 bends obliquely forwards in the direction of the outer wall 312.

The second flow channel 50 then enters the second housing section 32 through an opening 3555 in the dividing wall 35 and merges there with a section 56 into the heat exchanger 60.

In the heat exchanger 60, the section 56 of the second flow channel 50 runs in countercurrent to the section 46 of the first flow channel 40 obliquely downward in the direction of the inner wall 38 of the housing 30. After exiting the

Heat exchanger 60, the second flow channel 50 has a section 57 through a passage in the partition wall 36 into the third housing section 33 over. There the second flow channel 50 is connected to the suction side of a blower 54. The fan 54 is connected on the output side to an exhaust air outlet 58 extending horizontally through the housing wall 332 to the outside.

In the first housing section 31, near the inside of the housing 30 in the lower region, an electronic control 70 is arranged, which is shown in FIG

Signal connection 72 with a control unit 74 is. The control device 74 can be arranged stationary on the inside of the housing 30 or - as shown in FIG. 1 - as a wireless remote control. The control unit 74 calculates the required speed and thus the required volume flow of the fans 44 and 54 and the output of the preheating or cooling register 43 according to the temperature and humidity of the outside air, the temperature of the exhaust air and the desired temperature and humidity in the interior 100 and transmitted to the controller 70 for controlling these units.

The electronic control 70 is optionally wireless (e.g. via Bluetooth® or WLAN) or wired (via a LAN connection) in signal connection 72 with the control unit 74. The control unit 74 is optionally wireless (e.g. via

Bluetooth® or WLAN) or wired (via a LAN connection) integrated into a house network, so that the ventilation system 10 can also be used as an assembly within a more comprehensive SmartHome controller 76, the control device 74 or the regulator 70, for example, by means of their remote control and / or can be controlled by means of an app on a smartphone.

An accumulator 80 is arranged in the front part of the lower third housing section 33, which is supplied with electrical energy by, for example, photovoltaic modules 90 arranged on the outer surface of the outer wall 312 and / or 322 and / or 332 and is used for preferably self-sufficient electrical supply to the ventilation device 20. An additional supply of the ventilation device 20 when the charge level of the accumulator 80 is low is optionally provided. If the ventilation system 10 is installed in a room-high window or next to a door, the filling modules arranged below and / or above the housing 30 for height compensation can be used very well to accommodate additional ones Accumulators 80 and for attaching additional photovoltaic modules 90 are used.

In the figures 2 to 33 different installation situations of the

Ventilation system 10 according to the invention shown. Due to the wide range of installation options, both in the area of retrofitting when replacing windows or expanding the windows, for example in old buildings, as well as in the area of original equipment, especially in modern low-energy houses or zero-energy houses, the system according to the invention is versatile and easy to install. Due to the modular design, individual

Components can be replaced with other or new components with little effort.

In FIGS. 2A and 2B up to FIGS. 33 A and 33 B, the figure with the letter A shows a schematic front view and the figure with the letter B shows a cross-section of a specific installation situation.

Components of the same type are given the same reference number despite different installation situations.

In FIGS. 2A and 2B, a window 110 is arranged in a wall 120 which separates an interior 100 from an exterior 200. The interior 100 is delimited at the bottom by a floor 102 and at the top by a ceiling 104. The left side of the window 110 abuts a reveal 112 of the window opening in the wall 120. In the area of the right reveal is a

Ventilation device 20 is arranged, which preferably has the same height as the window 110. In order to be adapted to the height of a window 110, the ventilation device 20 can be lengthened at the top and / or at the bottom with fitting pieces or compensation modules (not shown) that can be arranged on the housing 30. Outside air is drawn in horizontally into the ventilation device 20 via the outside air inlet 41 perpendicular to the pane of the window 110. The outside air is fed to the inside of the ventilation device 20 via the supply air outlet 48 into the interior 100. The exhaust air is via an exhaust air inlet 51 arranged in the upper area Interior 100 is sucked into the ventilation device 20 and discharged into the exterior 200 via an exhaust air outlet 58 arranged in the lower area.

In FIGS. 3A and 3B, the installation situation from FIGS. 2A and 2B mirrored onto the left side of the window 110 is identical.

In FIGS. 4A and 4B, a ventilation device 20 is arranged next to a window 110 in the area of the inner wall of the interior 100. The ventilation device 20 is connected to the outside air inlet 41 for the fresh outside air by means of a duct 141 which penetrates the wall 120 to the outside. The exhaust air outlet 58 of the ventilation device 20 is also by means of the wall 120 to the outside

penetrating channel 158 connected to the outer region 200. After leaving the ventilation device 20, the outside air flows horizontally and / or downwards from its supply air outlet 48. The exhaust air inlet 51 is arranged at the top on the front side of the ventilation device 20.

The installation situation shown in FIGS. 4A and 4B is mirrored in the following FIGS. 5A and 5B on the left side of the window 110, which also rests with both outer sides against the two soffits 112 of the window opening.

In the installation example according to FIGS. 6A and 6B, the ventilation device 20 is installed in the area of the right reveal 112 of the window opening of the window 110. In a retrofit solution, the new window 110 can be extended by the width of the

Ventilation device 20, that is to say about 15 to 20 cm narrower, so that no structural changes to the wall 120 are necessary. Due to the vertical arrangement, the ventilation device 20 is made relatively slim and has a width of about 15 to 20 cm. The outside air 41 is sucked in from the outside area 200 parallel to the pane of the window 110 in the upper area of the ventilation device 20. The exhaust air 158 is also released parallel to the pane of the window 110 in the lower area of the ventilation device 20 to the outer area 200. The exhaust air inlet 51 is arranged in the upper region of the ventilation device 20 on the side of the interior 100. The supply air outlet 48 is arranged in the lower region of the ventilation device 20 on the side of the interior 100. The installation situation shown in FIGS. 6A and 6B is mirrored in the following FIGS. 7A and 7B on the left side of the window 10 and apart from that, identical.

In FIGS. 8A and 8B, a ventilation device 20 is arranged on the inside of the wall 120 at a distance to the right of a window 110. The ventilation device 20 is connected to its outside air inlet 41 via a duct 141 which is arranged in an opening in the wall 120 and is angled into the area of the right reveal 112 on the outside of the window 110. The

Ventilation device 20 is also with its exhaust air outlet 58 with one in one

Through the wall 120 arranged and angled in the area of the right reveal 112 on the outside of the window 110 opening channel 158 connected. The supply air outlet 48 is provided in the lower area of the ventilation device 20 on the inside thereof and the exhaust air inlet 51 is arranged in the upper area of the ventilation device 20.

The installation example shown in FIGS. 8A and 8B is mirrored in FIGS. 9A and 9B on the left side of the window 110 and is otherwise identical.

In FIGS. 10 A and 10 B, the ventilation device is arranged in the area of the right reveal 112 of the window 110. The outside air inlet 41 is in the upper area on the outside and the exhaust air outlet 58 in the lower area on the

Outside of ventilation device 20. Ventilation device 20 is additionally provided in the upper area with a channel 151 which runs on the inside of wall 120 to a wall 130 which separates interior 100 from an adjacent room 160. The channel 151 passes through the wall 130 and can thereby also suck out exhaust air from the room 160 into the ventilation device 20. The supply air outlet 48 also supplies this space 160 with supply air by flowing over it by way of natural pressure equalization, for example via gaps in a door (not shown) in the wall 130. The exemplary embodiment shown in FIGS. 10 A and 10 B is mirrored in FIGS. 11 A and 11 B on the left side of the window 110 and is otherwise identical.

In the embodiment shown in Figures 12 A and 12 B, this is

Ventilation device 20 arranged at a distance from the right reveal 112 of the window 110 on the inside of the wall 120. The outside air inlet 41 is connected to the outside area 200 via a duct 141 running through the wall 120

connected. The exhaust air outlet 58 of the ventilation device 20 is also connected to the outside area 200 via a channel 158 penetrating the wall 120. In the area of the exhaust air inlet 51, the ventilation device 20 has a connection to a horizontally running channel 151 which penetrates a side wall 130 of the interior space 100 and is thus connected to an adjacent room 160. The supply air outlet 48 also supplies the room 160 with supply air by means of natural pressure equalization through overflow, for example via gaps in a door (not shown) in the wall 130.

The exemplary embodiment shown in the following FIGS. 13 A and 13 B again corresponds to the exemplary embodiment according to FIGS. 12 A and 12 B in the form mirrored on the left side of the window 110.

In FIGS. 14 A and 14 B, the ventilation device 20 is installed in the area of the right reveal 112 of the window 110. The outside air inlet 41 lies in the upper area of the ventilation device 20 parallel to the pane of the window 110. The exhaust air outlet 58 in the lower area of the ventilation device 20 is also parallel to the pane of the window 110. A duct 151 located on the inside of the wall 120 connects an adjacent room 160 with the exhaust air inlet 51 of the

Ventilation device 20. The supply air outlet 48 also supplies the room 160 with supply air by means of natural pressure equalization by overflow, for example via gaps in a door (not shown) in the wall 130. FIGS. 15 A and 15 B show the exemplary embodiment according to FIGS. 14 and 14 B in mirrored form on the left side of the window 110. The exemplary embodiment according to FIGS. 16 A and 16 B differs from the exemplary embodiment shown in FIGS. 14 A and 14 B in that the ventilation device 20 is not arranged in the area of the soffit but on the inside of the wall 120 at a distance from the window opening. In this case, the ventilation device 20 is connected with its outside air inlet 41 via a channel 141 penetrating the wall 120 via the reveal 112 with the outside area 200 in such a way that the outside air flows in parallel to the pane of the window 110. The exhaust air outlet 58 of the ventilation device 20 is via a wall 120

The penetrating channel 158 is connected to the outer area 200 via the reveal 112 in such a way that the exhaust air flows out in the lower area of the ventilation device 20 parallel to the pane of the window 110. In FIGS. 17 A and 17 B, the exemplary embodiment just described in accordance with FIGS. 16 A and 16 B is mirrored onto the left side of the window 110 and is otherwise identical.

In the exemplary embodiment according to FIGS. 18 A and 18 B, the ventilation device 20 is arranged in the area of the right reveal 112 of the opening of the window 110. Outside air inlet 41 and exhaust air outlet 58 are on the outside of the

Ventilation device 20 and are directly connected to the outside area 200. A duct 148 runs on the inside of the wall 120, which connects the outside air outlet 48 through a wall 130 with an adjacent room 160 and provides fresh air there. The exhaust air from the adjacent room 160 is in this case by means of natural pressure equalization through overflow

for example, via gaps in a door (not shown) in the wall 130 to the exhaust air inlet 51 of the room 100. In Figure 19 A and 19 B this is

Embodiment according to FIGS. 18 A and 18 B mirrored on the left side of the window 110 and otherwise identical.

In the exemplary embodiment according to FIGS. 20 A and 20 B, the ventilation device 20 is arranged on the inside of the wall 120 at a distance from the right reveal 112 of the window 110. The outside air inlet 41 is connected to the outside area 200 via a duct 141 penetrating the wall 120. Of the

Exhaust air outlet 58 is connected to the outside area 200 via a duct 158 breaking through the wall 120. The supply air outlet 48 is on the wall 120 guided channel 148, which penetrates a wall 130, in connection with an adjacent room 160 and also supplies this with fresh air 48. The exhaust air from the adjacent room 160 is in this case by means of natural pressure equalization by overflow, for example via gaps in a door, not shown, in the wall 130 to the exhaust air inlet 51 of the room 100. The exemplary embodiment described in FIGS. 20 A and 20 B is mirrored in FIGS. 21 A and 21 B on the left-hand side of the window 110 and is otherwise identical.

The exemplary embodiment illustrated in FIGS. 22 A and 22 B differs from the exemplary embodiment shown in FIGS. 20 A and 20 B in that the ventilation device 20 is in the area of the right reveal 112

is arranged. Otherwise it is identical to this exemplary embodiment. The exemplary embodiment according to FIGS. 23 A and 23 B corresponds to that of FIGS. 22 A and 22 B with a reflection on the left side of the window 110.

In the exemplary embodiment according to FIGS. 24 A and 24 B, the ventilation device 20 is arranged on the inside of the wall 120 at a distance from the right reveal 112 of the window 110. The outside air inlet 41 is connected to a horizontal duct 148 via an opening in a wall 130 with an adjacent room 160 and supplies it with supply air 48 141 and 158 connected. In contrast, FIGS. 25 A and 25 B are again on the left side of window 110

mirrored and otherwise identical.

The exemplary embodiment according to FIGS. 26 A and 26 B shows a ventilation device 20 installed in the area of the right reveal 112 of the window 110, the exhaust air inlet 51 of which by means of a duct 151 running vertically and then horizontally under or preferably integrated in the ceiling 104 of the interior 100 is connected to a neighboring room, not shown, and its exhaust air 51 is disposed of in addition to that of the interior 100 via the exhaust air outlet 58. In FIGS. 27A and 27B show this exemplary embodiment again mirrored on the left side of the window 110.

28A and 28B differ from FIGS. 26A and 26B in that the ventilation device 20 is again arranged there on the inside of the wall 120 instead of in the area of the reveal 112. The outside air inlet 41 is connected to the outside area 200 via a duct 141 penetrating the wall 120. Of the

Exhaust air outlet 58 is connected to the outside area 200 via a duct 158 breaking through the wall 120. A duct 151, which initially runs vertically and then horizontally, preferably integrated in the ceiling 104 of the interior space 100, connects the exhaust air inlet 51 of the ventilation device 20 to an adjacent room (not shown). In FIGS. 29A and 29B, this installation situation is shown mirrored again on the left side of the window 110.

In FIGS. 30A and 30B, the ventilation device 20 is installed again in the area of the right reveal 112. The additional connection of another, not shown

Space to the exhaust air inlet 51 by means of a channel 151 corresponds to this

Exemplary embodiment according to FIGS. 28A and 28B. In FIGS. 31 A and 31 B, this installation situation is shown mirrored again.

In FIGS. 32A and 32B, the ventilation device 20 is again arranged on the inside of the wall 120 instead of in the area of the reveal 112. The outside air inlet 41 is connected to the outside area 200 via a duct 141 penetrating the wall 120. The exhaust air outlet 58 is connected to the outside area 200 via a duct 158 breaking through the wall 120. The additional connection of a further space, not shown, to the exhaust air inlet 51 by means of a duct 151 corresponds to the exemplary embodiment according to FIGS. 28A and 28B. In FIGS. 33A and 33B, this installation situation is shown mirrored again.

In Figure 34, a housing 30 is shown in the unequipped state. The

Housing 30 comprises an upper housing wall 34, a lower housing wall 37 and horizontal partition walls 35 and 36 arranged spaced apart therebetween. The partition walls 35 and 36 convert the housing into an upper first Housing section 31, divided into a middle second housing section 32 and a lower third housing section 33. Outwardly becomes the first

Housing section 31 from an outer wall 312, the second housing section 32 from an outer wall 322 and the third housing section 33 from one

Bounded outer wall 332, wherein outer wall 312, 322 and 332 form a common continuous outer wall.

In the outer wall 312 of the first housing section 31, the outside air inlet 41 is provided as an opening. The exhaust air outlet 58 is provided as an opening in the outer wall 332 of the third housing section 33.

The upper partition wall 35 has a first opening 3545 for the passage of the flow channel section 45 and a second opening 3555 for the passage of the flow channel section 55. Lower partition 36 has a first opening 3657 for the passage of the flow channel section 57 and a second opening 3647 for the passage of the flow channel section 47.

The housing 30 can be formed, for example, as a plastered housing made of expanded polypropylene (EPP) and is then inserted, fixed and plastered in the area of the reveal 112 or a wall opening in the wall 120 for pre-assembly. If necessary, channels for the outside air or the exhaust air are also docked to the corresponding openings in the housing 30. Subsequently, the individual modules of the ventilation device 20 are inserted into the housing sections 31, 32 and 33 from the inside of the housing 30, connected to one another in a sealing manner and coupled to the required connections and signal lines.

The ventilation system 10 according to the invention is versatile due to the modular structure and the diverse connection options of the ventilation device 20 and can be easily adapted to new technical developments at any time by simply replacing components, without further structural measures after the one-time integration of the housing 30 in the wall 120 or the reveal 112 to have to make. List of reference symbols

10 ventilation system

20 ventilation unit

30 cases (of 20)

31 (first) housing section

312 outer wall (of 31)

32 (second) housing section

322 outer wall (of 32)

33 (third) housing section

332 outer wall (of 33)

34 (upper) housing wall

35 partition or partition (from 30, between 31 and 32)

3545 opening (in 35 for 45)

3555 opening (in 35 for 55)

36 partition or partition (from 30, between 32 and 33)

3647 opening (in 36 for 47)

3657 opening (in 36 for 57)

37 (lower) housing wall

38 inner wall (of 30)

40 (first) flow channel

41 outside air inlet (from 200 to 40)

42 filters (in 41)

43 Preheating / or cooling coil

44 blowers (in 40)

45 section (from 40, before 60)

46 section (from 40 to 60)

47 section (from 40 to 60)

48 outside air outlet (in 100)

50 (second) flow channel

51 exhaust air inlet (from 100 to 50)

52 filters (in 51)

53 muffler (in 50) Blower (in 50)

Section (from 50, before 60)

Section (from 50 to 60)

Section (from 50 to 60)

Exhaust air outlet (in 200)

Heat exchanger

regulation

Signal connection

Control unit

SmartHome control

accumulator

Photovoltaic module

(Inner space

Floor (out of 100)

Ceiling (out of 100)

window

Window frames

Reveal

wall

Section of 120

Opening (in 120)

wall

Passage

Duct (for 41)

Duct (for 48)

Duct (for 51)

Duct (for 58)

(another to 100 adjacent) room outside area

Claims

Claims

1. A ventilation system (10) for at least one room (100), comprising

at least one ventilation device (20) with at least one housing (30), which has a first flow channel (40) with at least one fan (44) arranged therein for conveying outside air into the room (100) and at least one second flow channel (50) with at least a fan (54) arranged therein for conveying exhaust air from the room (100), the first flow channel (40) and the second flow channel (50) each running with a section (46; 56) in the region of a heat exchanger (60) , characterized in that the housing (30) of the ventilation device (20) is modularly divided into at least three housing sections (31; 32; 33) by means of at least two partition walls or partition surfaces (35; 36) arranged essentially perpendicular to the main flow direction of the outside air and the exhaust air is and that at least one of the fans (44; 54) on the room (100)

facing away from the flow channels (40; 50) is arranged.

2. Ventilation system according to claim 1, characterized in that a preheating and / or cooling register (43) is arranged in the first flow channel (40) near an outside air inlet (41).

3. Ventilation system according to one of the preceding claims, characterized in that the heat exchanger (60) is designed as an enthalpy heat exchanger.

4. Ventilation system according to one of the preceding claims, characterized in that in the first flow channel (40) close to one

Outside air inlet (41) and / or in the second flow channel (50) near an exhaust air inlet (51) at least one filter (42; 52) is arranged.

5. Ventilation system according to one of the preceding claims, characterized in that the flow channels (40; 50) with their Heat exchanger (60) associated sections (46; 56) in one

Countercurrent arrangement are arranged.

6. Ventilation system according to one of the preceding claims, characterized

characterized in that at least one silencer (53) is arranged in at least one of the flow channels (40; 50).

7. Ventilation system according to one of the preceding claims, characterized

characterized in that the ventilation device (20) on a reveal (112) of a window (110) or on the inside of a room (100)

limiting wall (120) or in an opening (124) of the wall (120) is arranged in such a way that the housing sections (31; 32; 33) are positioned vertically one above the other.

8. Ventilation system according to one of the preceding claims, characterized

characterized in that a control (70) for the ventilation device (20) is arranged in one of the housing sections (31; 32; 33).

9. Ventilation system according to claim 8, characterized in that the

Control (70) is in signal connection (72) with a control unit (74).

10. Ventilation system according to claim 8 or 9, characterized in that the regulation (70) and / or the control device (74) is part of a higher-level SmartHome control (76) or in coordination with this

communicates.

11. Ventilation system according to one of the preceding claims, characterized

characterized in that at least one photovoltaic module (90) and an accumulator (80) for storing the energy for the ventilation device (20) are arranged in at least one of the housing sections (31; 32; 33).

12. Ventilation system according to one of the preceding claims, characterized in that at an inlet (41; 51) and / or an outlet (48; 58) at least one of the flow channels (40; 50) at least one channel (141, 148; 151, 158) to redirect the air and / or to

Forwarding the air into or from an adjacent room (160) is provided.

13. Ventilation system according to claim 12, characterized in that the channel (141, 148; 151, 158) for deflecting the air and / or for

Forwarding of the air with a passage (132) passes through a wall (130) delimiting the room (160) or is connected to at least one air duct arranged in a floor (102) or a ceiling (104) of the room.