DE20106814U1 - Ventilation device with heat recovery on windows - Google Patents

Description

Ventilation system with heat recovery on windows

The invention serves to recover heat stored in the interior of buildings by means of a ventilation device on windows.

It is known that facilities for controlled ventilation with heat recovery can be used. These are necessary in heavily insulated living spaces in order to keep heat loss and humidity in the interior to a minimum.

According to DE 298 08 237 Ul, a device for home ventilation with heat recovery is proposed in which no additional wall openings are provided for air exchange, but instead the wall openings inevitably required by the installation of a roller shutter are used. A ventilation device equipped with heat recovery elements is integrated into the box housing belonging to the roller shutter. Used room air that is discharged to the outside gives off some of its heat to the heat recovery elements and is stored in them. The flow direction is reversed by a timer, i.e. fresh air is led from outside into the interior. The heat recovery elements give off their stored heat to the fresh air and preheat the fresh air before it enters the interior.

The disadvantage of this system is that in order to implement ventilation with heat recovery, a roller shutter box is absolutely necessary to accommodate the heat recovery elements. In addition, the constant change in the direction of air flow and the installation of heat recovery elements are associated with high technical and therefore costly expenditure.

The object of the invention is to integrate a ventilation device with heat recovery into conventional windows and thus to reduce the heat losses occurring through the windows.

According to the invention, the object is achieved by the features of claim 1. The invention is used in windows with triple glazing, which are framed by a common sash frame.

The middle pane of triple glazing forms two adjacent chambers. The inner chamber is delimited on the one hand by the inner pane, which is made of insulating glass, and on the other hand by the middle pane, while the outer chamber is delimited on the one hand by the outer pane, which is also made of insulating glass, and on the other hand by the middle pane. The middle pane is preferably made of glass with high thermal conductivity.

Air supply ducts and air exhaust ducts are provided in the side frame parts of the sash frame, which allow air to enter and exit the chambers. The air supply ducts and air exhaust ducts are equipped with micro fans, micro filters and air drying elements.

The invention is explained in more detail using an embodiment. The accompanying drawings show in

Fig. 1 is a side view of a window in section, in which the chambers are flowed through by the warm air and the cold air in the countercurrent principle,

Fig. 2 is a side view of a window in section, in which the chambers are flowed through by warm air and cold air in the direct current principle.

According to the present invention, the ventilation device with heat recovery is used on windows with triple glazing. In Fig. 1, the window 1 is formed by the sash frame 2 and the panes 3, 4 and 6 framed by the sash frame 2. The window 1 closes the wall opening and forms the thermal separation between the interior 13 of the building and the outside 14 of the building.

By designing window 1 with triple glazing, chambers are formed between the panes through which air flows, as described below.

The inner chamber 5 is formed by the inner pane 3 and the middle pane 4 spaced apart from it, the outer chamber 7 is formed by the outer pane 6 and the middle pane 4 spaced apart from it. The inner pane 3 and the outer pane 6 are made of insulating glass, while the middle pane 4 is made of a glass with high thermal conductivity.

The air is guided through the chambers 5, 7 via air supply ducts and air discharge ducts which are located in the upper and lower horizontal frame parts 8, 9 of the sash frame 2.

According to Fig. 1, the warm air 10 is guided from the interior 13 of the building via the air supply duct 12 located in the upper horizontal frame part 8 into the outer chamber 7 and from there via the air discharge duct 15 located in the lower horizontal frame part 9 to the outside 14 of the building. In order to ensure that the warm air 10 is guided over the entire area in the chamber 7, both the air supply duct 12 and the air discharge duct 15 are provided with adjacent inlet openings 22 and outlet openings 23 over their entire length.

At the same time, the cold air 11 is fed to the inner chamber 5 via the air supply duct 16 arranged in the lower horizontal frame part 9 and is guided into the interior 13 of the building via the air discharge duct 17 arranged in the upper horizontal frame part 8. Here, too, both the air supply duct 16 and the air discharge duct 17 are equipped with corresponding inlet openings 24 and outlet openings 25 arranged next to one another over the entire length for the surface-wide guidance of the cold air 11 in the inner chamber 5.

In order to prevent a so-called short circuit of warm air 10 and cold air 11 between the adjacent channels, the entry and exit of the air from the corresponding channels is realized via openings located at a distance from one another. The entry of the warm air 10 into the air supply channel 12 takes place via an inlet opening 30 arranged at one end of the upper horizontal frame part 8, while the exit of the cold air 11 from the air discharge channel 17 takes place via an outlet opening 31 located at the opposite end of the upper horizontal frame part 8 and located at a distance from the inlet opening 30. Accordingly, in the lower, horizontal frame part 9 of the

The air supply duct 16 has an inlet opening 32 and the air discharge duct 15 has an outlet opening 33 located away from the inlet opening 32.

In the embodiment shown in Fig. 2, the air short circuit described above cannot occur due to the position of the inlet and outlet openings of the adjacent channels being separated by the window.

Through this air flow, the warm air 10 and the cold air 11 move past each other in countercurrent, separated by the middle pane 4, with the result that a temperature equalization takes place via the middle pane 4, which consists of a high-conductivity glass, in which the fresh air supplied to the interior 13 of the building is preheated. In addition, the fresh air in the chamber 5 is additionally heated by the temperature equalization taking place between the pane 3 and the chamber 5.

To generate a forced flow of both the warm air 10 and the cold air 11, a miniature fan 18 is arranged in the air supply ducts 12 and 16.

The air supply duct 12 is also equipped in its inlet area with a filter with air dryer 19, which dries the warm air 10 before it enters the outer chamber 7 and thus counteracts condensation in the chamber 7. The condensation decreases with constant use of the ventilation device according to the invention, since moisture is constantly removed from the interior.

The air supply duct 16 is equipped with a filter 20 in its inlet area, which prevents the entry of contaminated cold air 11 into the inner chamber 5.

Fig. 2 describes the air flow of warm air 10 and cold air 11 in the direct current principle. In this embodiment, both the warm air 10 and the cold air 11 are guided via air supply channels 26, 27 in the upper horizontal frame part 8 via the chambers 5, 7 to the air discharge channels 28, 29 in the lower horizontal frame part 9. In this special embodiment, the air supply channel 26 is located above the air supply channel 27 and the warm air 10 is fed via the air supply channel 27 into airtight tubular channels .21 of the outer chamber 7.

The invention has the advantage over the known prior art that preheated fresh air can be supplied to the interior of the building and thus the heat balance of the building can be improved.

It is clear to the person skilled in the art, without departing from the scope of the protection claims, that the air supply ducts with the correspondingly oppositely arranged air discharge ducts can be arranged at any point on the casement, provided that heat exchange between the air flowing past each other is ensured.

Furthermore, it is clear to the expert that the ventilation device according to the invention is not limited to heat recovery at windows alone. Another area of application arises from the increasing design of facades with glass elements. When a glass facade is designed with triple glazing according to the window described, the heat recovery values that occur are even more significant.

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List of reference symbols used

1 Window 2 Casement frame 3 Inner disc 4 Middle disc 5 Inner Chamber 6 Outer disc 7 Outer Chamber 8th Upper horizontal frame part 9 Lower horizontal frame part 10 Warm air 11 Cold air 12 Air supply duct 13 inner space 14 Outside 15 Air exhaust duct 16 Air supply duct 17 Air exhaust duct 18 Micro blowers 19 Filter with air dryer 20 filter 21 Tubular channels 22 Entrance openings 23 Outlet openings 24 Entrance openings 25 Outlet openings 26 Air supply duct 27 Air supply duct 28 Air exhaust duct 29 Air exhaust duct 30 Entrance opening 31 Outlet opening 32 Entrance opening 33 Outlet opening

Claims (6)

1. Ventilation system with heat recovery on windows ( 1 ) consisting of triple glazing framed by a common sash frame ( 2 ),
wherein the triple glazing defines an inner chamber ( 5 ) which is delimited by an inner pane ( 3 ) made of insulating glass and a middle pane ( 4 ) made of glass with high thermal conductivity and spaced apart from the inner pane ( 3 ).
and an outer chamber ( 7 ) delimited by an outer pane ( 6 ) made of insulating glass and the middle pane ( 4 ) spaced apart from the outer pane ( 6 ),
wherein the inner chamber ( 5 ) is assigned a first air supply duct ( 16 ) arranged in the sash frame ( 2 ) and a first air discharge duct ( 17 ) opposite the first air supply duct ( 16 ), and via inlet openings ( 24 ) located in the first air supply duct ( 16 ) and extending over its length, a surface entry of the cold air ( 11 ) from outside ( 14 ) into the inner chamber ( 5 ) is made possible and via outlet openings ( 25 ) located in the first air discharge duct ( 17 ) and extending over its length, an exit of the cold air ( 11 ) into the interior ( 13 ) of the building is made possible,
and the outer chamber ( 7 ) is assigned a second air supply duct ( 12 ) arranged in the sash frame ( 2 ) and a second air discharge duct ( 15 ) opposite the second air supply duct ( 12 ), and openings ( 22 ) located in the second air supply duct ( 12 ) and extending over its length enable a surface entry of warm air ( 10 ) from the interior ( 13 ) of the building into the outer chamber ( 7 ) and an exit of the warm air ( 10 ) to the outside ( 14 ) is made possible via openings ( 23 ) located in the second air discharge duct ( 15 ) and extending over its length. 2. Ventilation device according to claim 1, wherein the air supply duct ( 12 ) for the supply of warm air ( 10 ) in the inlet area is equipped with a filter with air dryer ( 19 ) for drying the warm air ( 10 ). 3. Ventilation device according to claim 1, wherein the air supply duct ( 16 ) for the supply of cold air ( 11 ) is equipped in the inlet area with a filter ( 20 ) for cleaning the cold air ( 11 ). 4. Ventilation device according to claim 1, wherein the air supply ducts ( 12 ; 16 ) are equipped with micro fans ( 18 ) for sucking in both the warm air ( 10 ) and the cold air ( 11 ). 5. Ventilation device according to claim 1, wherein the warm air ( 10 ) enters the air supply duct ( 12 ) via an inlet opening ( 30 ) arranged at one end of the upper horizontal frame part ( 8 ), while the cold air ( 11 ) exits the air discharge duct ( 17 ) via an outlet opening ( 31 ) located at a distance from the inlet opening ( 30 ) and arranged at the opposite end of the upper horizontal frame part ( 8 ), and correspondingly in the lower horizontal frame part ( 9 ) the air supply duct ( 16 ) has an inlet opening ( 32 ) and the air discharge duct ( 15 ) has an outlet opening ( 33 ) located at a distance from the inlet opening ( 32 ). 6. Ventilation device according to claims 1 to 5, characterized in that the characterizing features are used on triple-glazed facades or facade elements.