DE102022110676A1 - Ventilation unit - Google Patents

Abstract

Ventilation device with a device housing (1) comprising a heat exchanger arranged in the device housing (1), at least two air inlet channels (14) for conducting an air volume flow to the heat exchanger, each with an air inlet (6) passing through the device housing 1 and at least two air outlet channels (13) for the line each of an air volume flow away from the heat exchanger, each with an air outlet (7) passing through the device housing 1, the heat exchanger extending continuously in a longitudinal direction (4) from a housing front wall (2) to a housing rear wall (3) and the air inlets (6) and the air outlets (7) on the top side (5) of the device housing (1) are each arranged on housing sides opposite one another in the transverse direction (8) of the device in such a way that the air inlets (6) and the air outlets (7) on the respective side of the housing are on one in Lines running in the longitudinal direction (4) of the housing are arranged one behind the other.

Description

The present invention relates to a ventilation device for the ventilation of rooms, in particular living spaces, which also enables heat recovery from the respective air volume flow, for which the device is equipped with a heat exchanger. Plate air-air heat exchangers or rotary heat exchangers are installed in ventilation devices to transfer heat from the exhaust air from the house to the fresh air supplied into the house from outside. The larger their heat transfer surface, the more heat can be transferred. The heat transfer surface of plate-air-air heat exchangers becomes larger when more plates are installed. This either increases the depth of the heat exchanger or moves the plates closer together, so that the air channels become narrower and the pressure loss in the heat exchanger increases. For ventilation devices with plate air-air heat exchangers, a compromise is therefore sought between the largest possible transfer area and the smallest possible device size. A larger heat transfer surface results in higher heat transfer and an improvement in heat recovery efficiency. A small device size with a large heat transfer area means a high pressure loss. The pressure loss must then be compensated for by fans installed in the ventilation device, which move the air volume flows. A higher pressure loss always results in a higher power consumption or an increased consumption of fan power.

In many ventilation devices, the plate air-to-air heat exchangers use the entire device depth to achieve the maximum possible heat transfer area or heat recovery efficiency.

In plate air-to-air heat exchangers, counterflows show the best heat recovery. The air inlets and the air outlets are each arranged on opposite sides of the device housing.

According to the prior art, the air inlets and outlets of ventilation devices suspended on a wall are arranged on the top of the device housing. In order to direct the air volume flow to the heat exchanger, two air ducts in the ventilation device must be led from above over both sides of the ventilation device to the heat exchanger. If the heat exchanger extends over the entire depth of the device, the air flow to the heat exchanger must also extend over the entire depth of the device on both sides. As a rule, the air inlets and outlets are arranged offset on the top of the ventilation device. Two air ducts can then extend side by side across the entire depth of the device on both the left and right sides. These air ducts arranged next to each other require appropriate installation space in the device housing, which increases the width of the device housing.

Based on this, the invention is based on the object of realizing a ventilation device with the most compact dimensions possible, particularly with regard to the device width.

This task is solved by the ventilation device with the features of claim 1 and further developed in the related claims.

The ventilation device initially has a heat exchanger that extends over the entire longitudinal direction of the device from the front wall of the device to the rear wall of the device. The air inlets at the ends of the air inlet channels and the air outlets at the ends of the air outlet channels are arranged on the top of the device housing and pass through this top to the interior of the housing. The air inlets and air outlets assigned to each other are arranged on opposite sides of the housing. The air inlets and outlets are arranged one behind the other on each side in a line running in the longitudinal direction of the housing. In this way, the width of the housing in the transverse direction of the device is significantly reduced. The air inlet and outlet channels are redirected in the device so that they extend in front of the heat exchanger over the entire length of the device in the direction of the longitudinal axis of the device and thus achieve maximum heat recovery with the existing components.

The bypass channel to bypass the heat exchanger is simply routed under the heat exchanger. The device depth in the longitudinal direction of the device and the device width in the device transverse direction are not influenced by the bypass channel in this way, and in particular are not increased. The bypass channel is directly connected to an air inlet channel and an air outlet channel. The bypass channel designed in this way does not increase the pressure loss in the device during bypass operation. Air volume flow and power consumption in heat recovery mode and in bypass mode therefore remain constantly the same.

The filter elements, which are preferably designed as filter inserts, are positioned at the air inlet in such a way that the air flows over the entire depth of the device in the direction of the longitudinal axis of the housing and is also distributed over it. In this way The largest possible filter area can be used. This minimizes the pressure loss on the filters. Thanks to a filter insert in front of a heating register, the heating register does not become dirty. By positioning this heating register in the air duct in front of the heat exchanger over the entire depth of the device in the direction of the longitudinal axis of the device, frost-free conditions can be achieved with less heating output. This also makes it possible to switch on site between a left-hand version and a right-hand version of the ventilation device. The ventilation device configured in this way enables the ventilation device to be arranged or mounted on the right or left side on site.

The invention is suitable for all ventilation devices with heat recovery using plate air-air heat exchangers and with a bypass duct.

• Das in der Zeichnungsfigur dargestellte Gerätegehäuse 1 weist zunächst eine dem Betrachter zugewandte Gehäusevorderwand 2 und eine in der Zeichnungsfigur dem Betrachter abgewandte Gehäuserückwand 3 auf. Die Gehäusevorderwand 2 und die Gehäuserückwand 3 begrenzen das Gerätegehäuse 1 in Gerätelängsrichtung 4. Die Oberseite 5 des Gerätegehäuses 1 ist auf jeder Gehäuseseite von einem Lufteinlass 6 und von einem mit dem jeweiligen Lufteinlass 6 korrespondierenden Luftauslass 7 auf der in Querrichtung 8 auf der jeweils gegenüberliegenden anderen Gehäuseseite durchbrochen, wobei die Querrichtung 8 rechtwinkelig zur Gehäuselängsrichtung 7 verläuft.

The invention is explained in further detail using the exemplary embodiment described below:

• The device housing 1 shown in the drawing figure initially has a housing front wall 2 facing the viewer and a housing rear wall 3 facing away from the viewer in the drawing figure. The front wall of the housing 2 and the rear wall of the housing 3 delimit the device housing 1 in the longitudinal direction 4 of the device. The top 5 of the device housing 1 is surrounded by an air inlet 6 on each side of the housing and by an air outlet 7 corresponding to the respective air inlet 6 on the opposite side in the transverse direction 8 The housing side is perforated, with the transverse direction 8 running at right angles to the longitudinal direction 7 of the housing.

Furthermore, in the lower part of the device housing 1, a hexagonal installation space 9 can be seen for a hexagonal heat exchanger, not shown in the drawing. A fan 10 adjoins the installation space 9 for moving an air volume flow through the device housing 1. Below the installation space 9, the bypass channel 11, which extends below the heat exchanger in the final assembly state, can be seen. Next to the bypass channel 11, a condensate tray 12 can be seen for collecting the condensate that occurs during operation of the ventilation device.

Below the air outlet 7 facing the viewer and shown in section, an air outlet channel 13 is shown. Analogously, the air inlet 6 shown in section facing the viewer shows the beginning area of a corresponding air inlet channel 14.

The front wall 2 of the housing is finally pierced by rectangular receiving openings 15, the two upper receiving openings 15 facing the top 5 of the device housing 1 running in the transverse direction 8 of the device, while the two receiving openings 15 ' arranged underneath run obliquely to the receiving openings 15 and to the transverse direction 8 of the housing. The receiving openings 15, 15' form so-called slots for receiving heating registers and/or filter elements, which are each designed as inserts, i.e. as heating register inserts or as filter inserts.

Reference symbol list

1

Device housing

2

Housing front wall

3

Housing back wall

4

Longitudinal direction of the housing

5

Top

6

Air intake

7

Air outlet

8th

Device transverse direction

9

Installation space

10

fan

11

Bypass channel

12

Condensate pan

13

Air outlet duct

14

Air intake duct

15.15'

Recording opening

Claims (8)

Ventilation device with a device housing (1) comprising • a heat exchanger arranged in the device housing (1), • at least two air inlet channels (14) for conducting an air volume flow to the heat exchanger, each with an air inlet (6) passing through the device housing (1), and • at least two air outlet channels (13) for conducting an air volume flow away from the heat exchanger, each with an air outlet (7) passing through the device housing (1), characterized in that the heat exchanger extends in a longitudinal direction (4) from a housing front wall (2) to a housing rear wall (3 ) extends continuously and that the air inlets (6) and the air outlets (7) on the top (5) of the device housing (1) are each on housings opposite one another in the transverse direction (8) of the device th are arranged so that the air inlets (6) and the air outlets (7) are arranged one behind the other on the respective side of the housing on a line running in the longitudinal direction (4) of the housing. ventilation device Claim 1 characterized in that the air inlet channels (14) and the air outlet channels (13) in the device housing (1) extend continuously in front of the heat exchanger in the longitudinal direction (4) of the housing. ventilation device Claim 1 or 2 characterized by a bypass channel (11) extending below the heat exchanger. ventilation device Claim 3 , characterized in that the bypass channel (11) is connected in terms of lines to an air inlet channel (14) and to an air outlet channel (13). Ventilation device according to one of the Claims 1 until 4 characterized by at least one filter element arranged in the air inlet channel (14). ventilation device Claim 5 characterized by a filter insert that can be inserted into a receiving opening (15,15`) in a housing wall, in particular the front wall (2) of the device housing (1), as a filter element. ventilation device Claim 5 or 6 , characterized in that at least two receiving openings (15, 15`) lying one behind the other in the flow direction are formed in the housing wall, the filter insert being arranged in front of a heating register insert in the flow direction. Ventilation device according to one of the preceding claims, characterized in that the heating register is arranged directly in front of the heat exchanger without an intermediate element.

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