WO2022128346A1 - Forced ventilation unit for ventilating a closed air chamber - Google Patents

Abstract

The invention relates to a forced ventilation unit (1) for ventilating a closed air chamber*** (2) between a wall (3, 3') and a piece of furniture (4) arranged in a room (5). The forced ventilation unit (1) can be arranged in or on the piece of furniture (4) and has at least one fan (11) and a heating unit (13), said heating unit (13) having an openable receiving area (14) for receiving electronic units which generate exhaust heat in the form of power loss, and the at least one fan (11) is designed to convey an input airflow (E), which is conducted through the heating unit (13) and is heated in the heating unit (13), out of the room and into the air chamber (2) in order to generate and/or regulate a microclimate in the air chamber (2).

Description

Forced ventilation unit for ventilation of a closed air space

Description:

The invention relates to a forced ventilation unit for ventilating a closed air space between a wall and a piece of furniture using waste heat given off by electronic units that can be arranged in the forced ventilation unit. Especially in new buildings, whose walls and especially their outer walls are usually not completely dry, but also in general in all buildings that have cold or wet walls, it can happen between the walls or outer walls and the furniture standing on them or mold growth in the air space between the walls and the furniture.

Such mold formation is caused by the temperature difference between the wall surface of the respective wall and the room or furniture temperature, the resulting difference in relative humidity and the restricted or completely prevented air circulation in the area between the piece of furniture and the wall or wall surface.

Various solutions for this are known from the prior art, which are mostly limited to blowing air into such an air space between a wall and a piece of furniture and thereby forcing air circulation or enabling natural convection.

Such systems are, however, in the case of an air space between the wall and the piece of furniture, which is essentially completely or at least partially closed off, for example, by additional walls, baseboards or at least one screen, thereby largely preventing a natural exchange of air, as is usually the case with built-in cupboards or kitchen furniture, cannot be used because the air blown or pumped into the air space cannot be discharged.

In addition, the systems known in the prior art only partially dissipate moisture already present in the intermediate space, since the air blown in or flowing through the air space is already partially saturated with moisture and can often only absorb small amounts of additional moisture and correspondingly dissipate it.

If there is already mold infestation, the mold spores are usually blown out of the air space in an uncontrolled manner by the known solutions and distributed throughout the room. Insofar as heating elements are provided in the systems known in the prior art for heating the air conveyed into the air space, this results in high energy consumption for heating the air flow, which is correspondingly expensive and therefore disadvantageous.

Also, the solutions, as they are often provided, cannot be hidden on or integrated into existing furniture, resulting in a visually unappealing sight.

The invention is therefore based on the object of overcoming the aforementioned disadvantages and providing a forced ventilation unit for ventilating a closed air space, which is designed to remove moisture present in the air space in an energy-efficient manner.

This object is achieved by the combination of features according to claim 1.

According to the invention, a forced ventilation unit is proposed for ventilation of an air space between a wall and a piece of furniture arranged in a room, which is closed off in particular by at least one panel, so that the temperature and humidity in the air space are set in a predetermined manner and a microclimate that prevails there is therefore generated and/or regulated can. Here, the wall can enclose the space at least in sections and thus form it. A closed air space between the wall and the piece of furniture is understood here to mean that the air circulation or the air exchange between the air space and the room is prevented or at least made more difficult without the forced ventilation unit according to the invention, so the air space can be completely or only partially blocked by a screen or other Elements must be completed, with natural air exchange being made more difficult or prevented. According to the invention, the forced ventilation unit can be arranged in or on the piece of furniture and has at least one fan and one heating unit on. The heating unit itself has an openable accommodation space for accommodating electronic units which generate waste heat as power loss. The at least one fan is designed here to promote an input air flow leading or flowing through the heating unit and being heated in the heating unit from the room into the air space for generating and/or regulating the microclimate prevailing in the air space.

The basic idea of the invention is to provide a forced ventilation unit which can be used to prevent mold on walls or behind furniture or in other hard-to-reach areas where no or only little natural air exchange is possible. For this purpose, the forced ventilation unit is preferably formed by the at least one fan, the heating of the input air flow by the waste heat from the electronic units and more preferably a corresponding control of these components to enable microclimate breeding or microclimate influencing in the air space, with this being achieved by using the waste heat when operating and/or charging the electronic units, very little additional energy has to be used to heat the input air flow.

The electronic units can be a wide variety of electrical devices and, for example, smartphones, tablets, notebooks, kitchen appliances, tools or their chargers and/or power packs.

Parallel to the need to prevent mold from forming behind furniture or other hard-to-reach areas, there is a situation in the private sphere as well as in the laboratory and office world that many sockets are occupied with power supply units and chargers for various electronic devices and are therefore blocked . These electronic devices or their Power packs or chargers usually generate a certain amount of power loss that occurs as waste heat, which has so far been dissipated into the room unused.

With the proposed solution, these electronic devices or their power packs or chargers can be arranged as electronic units in the receiving space, so that the waste heat can be used. As a result, not only is the waste heat used to heat the incoming air flow, thereby minimizing the energy consumption of the forced ventilation unit, but at the same time it also enables the electronic devices or electronic units to be stored in a visually appealing manner.

The electronic units that can be arranged in the receiving space can form the only heat source of the heating unit or the forced ventilation unit, so that the input air flow in such an embodiment can be heated exclusively by the waste heat or by the power loss of the electronic units. Accordingly, no additional energy has to be used to heat the air flowing through the heating unit, since this is available in any case.

The receiving space can be covered by a lid. If the forced ventilation unit is designed as a drawer, as explained later, the cover can be formed by an adjoining section of the piece of furniture in or on which the drawer is arranged.

However, since it can happen that too few electronic units are arranged in the receiving space or that the electronic units generally generate too little waste heat, it can be provided in an advantageous development that the heating unit also has a heating element, by which the input air flow can be heated. Such heating elements serve as additional heating, which are intended to compensate for insufficient heating of the input air flow by the waste heat from the electronic units. In this case, these heating units can be arranged in the heating unit Heating wires or also integrally formed by the at least one fan. In particular, the fan driving the input air flow can be controlled in such a way that a power loss in the form of waste heat is generated at it, which heats the input air flow. Since the at least one fan is present anyway, a further heat source does not necessarily have to be provided for this in addition to the fan and the electronic units. In order to enable the inlet air flow to be heated in a predetermined manner, the heating element can be controllable by a control device explained later in such a way that the air flowing along the inlet air flow is supplied with a predetermined amount of heat.

An advantageous variant, in which both an air flow (inlet air flow) with warm air can be supplied to the air space in a targeted manner and an air flow (outlet air flow) can be removed from the air space, provides that the forced ventilation unit has at least two fans, from which at least one first fan is designed to promote or generate the inlet air flow, and of which at least one second fan is designed to have an outlet which in particular leads or flows through the forced ventilation unit and promotes air from the air space into the room To promote or generate air flow. If the outlet air flow leads through the forced ventilation unit, any required screens or other components, such as e.g. B. filters, are particularly advantageously integrated into the forced ventilation unit.

A variant in which the at least one first fan is a radial fan and the at least one second fan is an axial fan is particularly advantageous here. Furthermore, the radial fan can be arranged such that it protrudes into the air space in such a way that the radial fan sucks in air axially through the heating unit, generating the input air flow, and the air along the input Air flow heated air blows out radially and preferably parallel to the wall in the air space. Although such a design is advantageous due to the prevailing space conditions and the desired flow or the desired flow directions of the respective air flow, it is also fundamentally possible to use an axial fan for the at least one first fan and/or one for the at least one second fan use radial fans.

The use of a radial fan is particularly advantageous because there is often very little space in the air space or in the air gap that defines the air space between the piece of furniture and the wall. When using an axial fan for the first fan, a sufficiently large distance between the fan and the wall or deflection means for deflecting the air flow would have to be provided, which is not necessary when using a radial fan or fan blowing out the air radially.

Since such tight space conditions in the room itself are not relevant, an axial fan can be used for the second fan, which is primarily due to its volume flow density of its V/p characteristic when sucking the air out of the air space via the air ducts leading the output air flow is optimal.

In order to be able to direct the air flows in a targeted manner and to prevent the inlet air flow and outlet air flow from mixing, the forced ventilation unit is provided with an outlet air duct and an inlet air duct in a likewise advantageous variant. The outlet air duct defines a flow path of the outlet air flow and the inlet air duct defines a flow path of the inlet air flow. Furthermore, the inlet air duct is formed at least in sections by the receiving space or is adjacent to it allowing heat transfer. The inlet air duct can also be formed entirely by the heating unit or the accommodation space of the heating unit. At an inflow-side end and at an outflow-side end of the inlet and/or outlet air duct, an inflow or outflow opening can also be provided as a ventilation opening in the forced ventilation unit, which can also be covered by a screen so that air can escape can flow into or out of the respectively adjoining areas outside of the forced ventilation unit, i.e. out of the room or the air space. Both the outlet air duct and the inlet air duct can be designed to be openable for maintenance purposes and, in particular, to be openable analogously to the receiving space.

Furthermore, the forced ventilation unit can be provided with at least one filter through which the outlet air flow can flow and which is designed to filter the outlet air flow. In this way, mold spores in particular, which are transported with the air from the air space by the outlet air flow and would otherwise be blown into the room, can be filtered out. If there is an outlet air duct, the filter can be arranged in it. A multi-stage filter is also possible.

However, a filter through which the input air flow can flow can also be provided, preferably on the room or inflow side of the input air flow, through which dust can be filtered from the air flowing in from the room, so that the electronic devices or electronic units cannot get through be contaminated or damaged by dust.

In order to control or regulate the forced ventilation unit and thereby also to control the exchange of air in the air space or the microclimate in the air space, the forced ventilation unit preferably also has a control device for controlling and/or regulating the at least one fan or all fans and/or the electronic units and—if present—the heating element. Corresponding technical control interfaces, for example, can be provided for communication with the electronic units. In a simple case, however, the electronic units can be controlled by controlling their respective power supplies. For example, individual or all electronic units can be supplied with voltage in a targeted manner according to a predetermined schedule. Additionally or alternatively, the forced ventilation unit can have a monitoring unit for monitoring the temperature of the heating unit and the electronic units that can be arranged therein, by means of which the heating unit and the electronic units can also be protected against overheating or damage. The monitoring unit can also be integrated into the control device, so that an exchange of data or information is also possible. Both the control device and the monitoring unit can be arranged in the receiving space or along the input air flow, so that any waste heat generated can be used directly to heat the input air flow. In particular, the control device also enables cyclic activation of the at least one fan, so that, for example, only the input air flow is generated in a first cycle and only the output air flow can be generated in a second cycle that is delayed from the first cycle. The control by the control device can also be made dependent on measured values from sensors, which can be connected to the control device. Such sensors can in particular be temperature and humidity sensors, which are arranged in the room and in the air space as well as in the forced ventilation unit and, for example, in the outlet and/or inlet air flow to record measured values be able. If a heating element is present, this can be controlled by the control device as a function of the temperature measured in the receiving space or in the heating unit, so that the heating element is controlled to generate additional heat if the waste heat given off by the electronic units is not sufficient for the input Air flow to heat incoming air in a predetermined manner.

The control device can thus be designed to control the forced ventilation unit or its components in such a way that a microclimate is generated in the air space according to predetermined parameters and/or that the microclimate prevailing there is specifically influenced, whereby humidity in the air space is increased, for example by combined cyclical heating and supplying air from the space into the air space and subsequently discharging the air that has been heated up and absorbs moisture in the air space from the air space.

Furthermore, the control device can also be designed to communicate with superordinate or subordinate systems. For example, the control device can communicate with a computer, a smartphone, a smart home control center, a cloud memory or a control of a ventilation system for data or command exchange.

Accordingly, according to an advantageous variant, the forced ventilation unit can have room sensors for detecting the temperature and/or the air humidity in the room and/or air space sensors for detecting the temperature and/or the air humidity in the air space and/or recording space sensors for detecting the Have temperature and / or humidity in the recording room. These can each be connected to the control device and/or the monitoring device in terms of signals. If the forced ventilation unit has sensors for detecting the temperature and/or the humidity and these are connected to the control device via signals, the control device is preferably designed to control the forced ventilation unit based on the (absolute) temperatures and/or humidity detected by the sensors or the differences detected To control temperatures and / or humidity, which can also be compared for example with predetermined characteristics or limit values.

For example, it can be provided that the at least one fan that generates the input air flow is then actuated to suck in air and blow it out into the air space, i.e. to generate the input air flow, if the room temperature measured by the room sensor is greater than that through the air space -Sensor measured air space temperature in the wall or in the air space or these temperatures deviate from each other by a predetermined tolerance value. Likewise, the at least one fan that generates the input air flow can alternatively or additionally be actuated to generate the input air flow if the air humidity measured by the air space sensor in the area of the wall or in the air space is greater than that measured by the room sensor Humidity in the room or if both humidity differ by a predetermined tolerance value.

Furthermore, it can advantageously be provided that the forced ventilation unit has at least one electrical supply line and/or voltage supply device for supplying voltage to the electronic units in the accommodation space. Furthermore, the forced ventilation unit can alternatively or additionally have at least one line duct for cable routing of cables leading from the electronics units out of the forced ventilation unit. In a simple case, a power distributor can be in the form of a multiple socket, whose individual slots can be designed to be controllable by the control device.

Furthermore, the forced ventilation unit can have, for example, a power pack as the voltage supply device, which can replace the power packs of the electronic units and can be advantageously designed for the heat transfer of the waste heat to the input air flow. Such a power pack can, for example, have cooling ribs through which the inlet air flow can flow.

In order to be able to subsequently integrate a forced ventilation unit according to the invention into a piece of furniture or to arrange it in a visually appealing manner, an advantageous embodiment also provides that the forced ventilation system is designed as a drawer that can be integrated into the piece of furniture and/or arranged underneath the piece of furniture. The forced ventilation system can replace a drawer in the piece of furniture. Furniture and in particular kitchen or laboratory furniture often have skirting boards or skirting boards which cover up a space between the floor and the underside of a piece of furniture. If the forced ventilation system is to be arranged underneath the piece of furniture, such a base panel can be removed in sections, for example, so that the forced ventilation system replaces it on the front of the furniture or on the room.

Alternatively, however, a forced ventilation unit can also be designed as a simple box, which can then be arranged, for example, in a drawer of the piece of furniture or on a surface or the mentioned space between the underside of the furniture and the floor.

If the forced ventilation unit is designed as a drawer, the drawer preferably has a room-side front part, a wall-side rear part and two opposing side parts connecting the front part to the rear part. Furthermore, the drawer can have an interior space that is open at the top and forms the receiving space, which can also define the entire heating unit. In a room surrounded by walls with floor and ceiling, the top is understood to be facing the ceiling and the bottom to be facing the floor, so that the drawer is therefore open on its side facing the ceiling. An inflow opening (ventilation opening) is formed on the front part, which is preferably covered by a panel, that is to say is covered. The input air flow can be sucked in through the inflow opening. At least one outflow opening (ventilation opening) is also formed on the rear part and/or one of the side parts, through which the heated input air flow can be blown out. The outflow openings can also be covered by a respective panel.

The visual impression of the furniture configuration is not adversely affected in particular by designing the forced ventilation system as a drawer and by designing the front part of the drawer accordingly.

Furthermore, the drawer can be designed so that its rear part protrudes beyond a rear side of the piece of furniture pointing towards the wall, so that air can be sucked in and/or blown out parallel to a plane defined by the rear side of the piece of furniture.

An outflow opening (ventilation opening) can also be formed on the front part, which can preferably be covered by a screen. The outlet air flow can be blown out into the room through the outflow opening. Furthermore, at least one inflow opening (ventilation opening) can be formed on the rear part and/or one of the side parts, through which the outlet air flow can be drawn in from the air space. At least one air guide element can also be provided within the heating unit and in particular within the receiving space, through which the incoming air flow can be guided along a predetermined flow path within the heating unit or the receiving space.

Furthermore, heat exchangers or cooling elements can be provided in the receiving space or between the receiving space and the incoming air flow, which allow sufficient transfer of the waste heat from the electronic units to the incoming air flow.

A further aspect of the invention relates to a forced ventilation system consisting of a large number of forced ventilation units according to the invention. These can each be arranged in or on different pieces of furniture adjoining a common air space. The forced ventilation system or one of the forced ventilation units can have a central control device for controlling and/or regulating all forced ventilation units of the forced ventilation system, with precisely one central control device preferably being provided.

In the case of the forced ventilation system consisting of a large number of forced ventilation units, it can also be provided that the forced ventilation units are designed differently within the disclosure according to the invention. For example, a first forced ventilation unit of the forced ventilation system can provide a radial fan as at least one first fan and a second forced ventilation unit of the forced ventilation system can provide an axial fan as at least one first fan.

The features disclosed above can be combined as desired, insofar as this is technically possible and they do not contradict one another. Other advantageous developments of the invention are characterized in the dependent claims or are presented in more detail below together with the description of the preferred embodiment of the invention with reference to the figures. Show it:

1 side view of a furniture configuration according to the prior art;

2 side view of a furniture configuration with a forced ventilation unit;

3 plan view of a first variant of the forced ventilation unit;

4 plan view of a second variant of the forced ventilation unit;

Figure 5 is a perspective view of a forced ventilation unit;

Figure 6 Perspective view of a forced ventilation system.

The figures are schematic by way of example. The same reference numbers in the figures indicate the same functional and/or structural features.

FIG. 1 shows a piece of furniture 4, such as a kitchen cupboard, in a side or side sectional view, with an air space between the piece of furniture 4 and the wall 3 or the floor 3′, which can also be regarded as a wall in simplified form 2 is formed. This is completed by an upper screen 41 and a base screen 42 . Although a gap 43 is provided in the area of the base panel 42, this is too small to allow sufficient air flow to prevent mold growth between the air space 2 and the space 5 in which the piece of furniture 4 is arranged. Correspondingly, with this configuration, which essentially corresponds to the prior art, a disadvantageous formation of mold in the air space 2 can occur. FIG. 2 discloses the structure according to FIG. 1, with the base panel 42 being replaced by a forced ventilation unit 1 according to the invention. The forced ventilation unit 1 enables the microclimate prevailing in the air space 2 to be specifically influenced, so that the air space 2 can be dehumidified and/or tempered in order to prevent mold growth. Accordingly, the forced ventilation unit 1 can generate an input air flow E from the space 5 into the air space 2, in which the air flowing through the forced ventilation unit 1 is heated by the waste heat from the electrical devices or electronic units arranged or arrangeable in the forced ventilation unit 1. The air from the air space 2 is also conveyed through the forced ventilation unit 1 by means of an outlet air flow A from the air space 2 into the space 5, so that moisture is also removed from the air space 2 with this air.

By heating the air flowing in via the input air flow E, its ability to absorb moisture is increased. In the air space 2 , the heated, supplied air absorbs at least part of the moisture present in the air space 2 . The saturated air is then discharged from the air space 2 via the outlet air flow A.

As an alternative to the arrangement of the forced ventilation unit 1 on or below the piece of furniture 4, a forced ventilation unit T configured as a drawer can be integrated into the piece of furniture 4, with a drawer of the piece of furniture 4 being replaced by the forced ventilation unit T configured as a drawer, which is shown in FIG 2 is shown in dashed lines. This can be optically adapted to the piece of furniture 4 or to the drawer of the piece of furniture 4 to be replaced, so that it fits optically into the piece of furniture 4 . For example, the forced ventilation unit T here protrudes beyond the rear 42 of the piece of furniture 4 and blows the air via the inlet air flow E and sucks the air via the outlet air flow A parallel to the plane formed by the rear 42 .

The forced ventilation unit 1 below the piece of furniture 4 or the forced ventilation unit T as a drawer integrated into the piece of furniture 4 can each be designed according to an embodiment shown in FIG. 3 or 4.

The forced ventilation unit 1 illustrated in FIG. In heating unit 13 there is accommodation space 14 for accommodating electronic units, a control device 16 for controlling forced ventilation unit 1 or its controllable components, and a voltage supply device 17 for supplying voltage to control device 16 and at least some of the electronics units that can be arranged in accommodation space 14. In the present case, the control device 16 is thus designed to control at least the first fan 11 , the second fan 12 and the voltage supply device 17 .

The two outlet air ducts 15 are preferably closed at the top by an openable cover, so that they can be easily opened for maintenance and cleaning. The heating unit 13 or the interior space forming the heating unit 13 of the forced ventilation unit 1 designed as a drawer is open at the top, but is covered by a component of the piece of furniture 4 when the drawer is in the closed state, so that the heating unit 13 also transmits the incoming air flow E is closed by the heating unit 13 enabling. Furthermore, an air inflow opening of the respective outlet air duct 15 is arranged on a side part S of the forced ventilation unit 1 so that air can be sucked in from the air space 2 at the side of the forced ventilation unit 1 .

(Fresh) air is drawn in from the space 5 by the heating unit 13 and heated along an inlet air flow E via the waste heat from electronic units arranged in the receiving space 14 . In the present case, it is also provided that the air flowing along the input air flow E is heated by waste heat from the control device 16 and the voltage supply device 17 . The electronic units that emit waste heat can be intentionally positioned in the receiving space 14 in order to use the waste heat that occurs anyway.

The air thus heated is then blown by the first fan 11 located on the rear part R of the forced ventilation unit 1 into the gap or air space 2 between the piece of furniture 4 and the wall 3 for the purpose of heating the air cushion located there. After sufficient heating of the air in the air space 2, the air located there or the air cushion located there can bind more humidity.

In a sequential cycle that is preferably staggered in time, the second fans 12 on the front part F guide the air that has been enriched with humidity along the outlet air flow A and via the outlet air duct 15, in which filters through which the outlet air flow A can flow can be arranged, into the Room 5 back. The filters in the outlet air duct 15 make it possible to clean air that is contaminated with mold spores or otherwise before or during the return transport into the room 5 . The present design of the forced ventilation unit 1 as a drawer enables simple installation, maintenance, cleaning and easy retrofitting of existing pieces of furniture 4 .

Electronic units, which until now have been converting their power loss into heat somewhere in space 5 in an uncontrolled manner, can be charged in a targeted manner (e.g. during night charging cycles) in the drawer or, more precisely, in the receiving space 14, so that the waste heat can be used appropriately and advantageously. The forced ventilation unit 1 also contributes to order and cleanliness in the room 5. In addition, a monitoring unit can be integrated into the control device 16, by means of which the voltage supply to the electronic units can be interrupted in the event of overheating or currents at which the electronic units would be damaged.

The forced ventilation unit 1 according to FIG. 4 is constructed very similarly to the forced ventilation unit 1 according to FIG. 3. A major difference is that the forced ventilation unit 1 according to FIG. so that the air is sucked in at the rear of the forced ventilation unit 1, conveyed along the outlet air flow A and blown out of the forced ventilation unit 1 at the front. Furthermore, only a first fan 11 is provided, which drives the input air flow E. This leads through the receiving space 14, in which air guide elements (not shown) are arranged, which meander the input air flow E through the interior or the receiving space 14, so that waste heat from the electronic units present there can be absorbed and dissipated as evenly as possible.

A variant of the forced ventilation unit 1 arranged in a piece of furniture 4 is shown in FIG or protrudes. The inflow opening of the outlet air duct 15 extends essentially from one of the side parts S to the opposite side part S, so that air can flow in over almost the entire width of the forced ventilation unit 1 . Furthermore, the air from the air space 2 can also flow in via the side part S adjoining the outlet air duct 15, in which side part S additional inflow openings can be provided for this purpose. As a result, air can also be sucked in from an air space 2 which extends between two adjacent pieces of furniture 4 or one piece of furniture 4 and another laterally adjacent wall. The first fan 11 is designed here as a radial fan, whereby a high pressure build-up can be achieved in the narrow air gap or air space 2, which is not easily possible with an axial fan because of the tight space conditions in the air space 2. The arrangement of the first fan 11 in the air space 2 accommodates the flat design due to the design as a radial fan. In particular, the design as a radial fan enables the first fan 11 to draw in the air axially along the inlet air flow E and preferably to blow out the air drawn in along the inlet air flow E radially parallel to the wall 3.

As in Figures 3 and 4, the second fan 12 is also designed as an axial fan, which here due to its functional volume flow rate of its V / p characteristic when sucking the air along the output air flow A via the output air ducts 15, because of the space-related and flow-related conditions for which axial suction and suction is optimal.

In the present case, the positioning of the room sensors 51, which measure the temperature and the humidity in the room 5, the positioning of the receiving room sensors 18, which measure the temperature and measure the air humidity in the receiving space 13, and the positioning of the air space sensors 21 which measure the temperature and the air humidity in the air space 3 are shown. Sensors 18, 21, 51 are each connected in terms of signals to control device 16, not shown in FIG.

Both the absolute values of the temperatures and humidity levels measured by sensors 18, 21, 51 and the differences between the temperatures and humidity levels between room 5, air space 2 and forced ventilation unit 1 are relevant. The at least one first fan 11 that generates the input air flow E can, for example, be controlled to draw in air and blow it out into the air space 2, i.e. to generate the input air flow E, if the room temperature measured by the room sensor 51 is greater than the room temperature measured by air space temperature measured by the air space sensor 21 in the area of the wall 3 or in the air space 2. It is also the case that the at least one first fan 11 generating the input air flow E is preferably controlled alternatively/additionally if a temperature measured by the air space sensor 21 in the area of the wall 3 or in the air space 2 is greater than the air humidity measured by the room sensor 51 in the room 5.

In Figure 6, two forced ventilation units 1, T, similar to the variant from Figure 5, are arranged adjacent to one another in a respective piece of furniture 4, 4', with the first fan 11 for promoting the inlet air flow E in the forced ventilation unit 1 on the right-hand side in the plane of the representation as in the Forced ventilation unit 1 according to FIG. 5 is also designed as a radial fan and the second fan 12 for promoting the output air flow A is designed as an axial fan, but no inflow of air via the side parts S is possible. In the case of the forced ventilation unit T on the left in the representation level, which is otherwise identical to the right-hand forced ventilation unit 1, the first fan 11' is designed as an axial fan which, due to its design, is installed in such a way that the air can be deflected during intake or on the intake side and blown out parallel to the wall 3. The forced ventilation units 1, 1' or other forced ventilation units (not shown) can be connected to one another in a cascade-like manner and controlled by a central control device. As shown, not all forced ventilation units have to be of identical design, but can take certain ambient conditions into account through the respective piece of furniture 4, 4' and/or a respective adjoining section of the wall 3. Correspondingly, however, all forced ventilation units of a forced ventilation system can also be designed identically. The control device, not shown, can be used to control the forced ventilation units 1, 1', for example, in such a way that initially the forced ventilation unit 1' on the left in the illustration generates an input air flow E into the air space 2 and, at a different time or at the same time, an output air flow A are generated from the air space 2 by the forced ventilation unit 1 on the right in the image plane and vice versa.

The implementation of the invention is not limited to the preferred exemplary embodiments given above. Rather, a number of variants are conceivable which make use of the solution shown even in the case of fundamentally different designs.

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Claims

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Claims Forced ventilation unit (1) for ventilating a closed air space (2) between a wall (3, 3') and a piece of furniture (4) arranged in a room (5), the forced ventilation unit (1) in or on the piece of furniture (4) can be arranged and has at least one fan (11) and a heating unit (13), the heating unit (13) having an openable accommodation space (14) for accommodating electronic units which generate waste heat as power loss, and the at least one fan (11) is formed, an input air flow (E) leading through the heating unit (13) and warming up in the heating unit (13) from the room into the air space (2) for generating and/or regulating a microclimate prevailing in the air space (2). to promote. Forced ventilation unit according to claim 1, wherein the heating unit (13) further comprises a heating element, by which the input air flow (E) can be heated. Forced ventilation unit according to Claim 1 or 2, having at least two fans (1 1 , 12), of which at least a first fan (11) is designed to promote the input air flow (E), and of which at least a second fan (12) is designed to promote an outlet air flow (A) that leads in particular through the forced ventilation unit (1) and conveys air from the air space (2) into the space (5). Forced ventilation unit according to the preceding claim, wherein the at least one first fan (11) is a radial fan and the at least one second fan (12) is an axial fan. Forced ventilation unit according to the preceding claim 3 or 4, with an outlet air duct (15), which determines a flow path of the outlet air flow (A), and an inlet air duct, which is formed at least in sections by the receiving space (14) or on it abuts allowing heat transfer and defining a flow path of the input air flow (E). Forced ventilation unit according to one of the preceding Claims 3 to 5, having at least one filter through which the outlet air flow (A) can flow and which is designed to filter the outlet air flow (A). Forced ventilation unit according to one of the preceding claims, further comprising a control device (16) for controlling and/or regulating the at least one fan (11) and/or the electronic units and/or a monitoring unit for monitoring the temperature of the heating unit (13) and the electronic units which can be arranged therein. Forced ventilation unit according to one of the preceding claims, having room sensors (51) for detecting the temperature and/or the air humidity in the room (5) and/or having air space sensors (21) for detecting the temperature and/or the air humidity in the Air space (2) and/or having receiving space sensors (18) for detecting the temperature and/or the humidity in the receiving space (14). Forced ventilation unit according to one of the preceding claims, having at least one electrical supply line and/or voltage supply device (17) for supplying voltage to the electronic units in the receiving space (14) and/or having at least one cable duct for routing cables leading from the electronic units out of the forced ventilation unit (1). Forced ventilation unit according to one of the preceding claims, wherein the forced ventilation system (1) is designed as a drawer which can be integrated into the piece of furniture (4) and/or arranged underneath the piece of furniture (4). Forced ventilation unit according to the preceding claim, wherein the drawer has a room-side front part (F), a wall-side rear part (R) and two opposite side parts (S) connecting the front part (F) to the rear part (R), the drawer having one upwards has an open interior space forming the receiving space (14), with an inflow opening being formed on the front part (F) through which the incoming air flow (E) can be drawn in, and on the rear part (R) and/or at least one of the side parts ( S) at least one outflow opening is formed, through which the heated input air flow (E) can be blown out. Forced ventilation unit according to the preceding claim, wherein the drawer is designed so that its rear part (R) protrudes beyond a rear side (42) of the piece of furniture (4) pointing towards the wall, so that at the rear part air is parallel to a defined by the rear side of the piece of furniture Level can be sucked in and/or blown out. - 26 - Forced ventilation unit according to one of the two preceding claims and claim 3, wherein an outflow opening through which the outlet air flow (A) can be blown out is formed on the front part (F), and on the rear part (R) and/or at least one the side parts (S) have at least one inflow opening through which the outlet air flow (A) can be sucked in. Forced ventilation system (10) consisting of a plurality of forced ventilation units (1) according to one of the preceding claims, wherein the forced ventilation system (10) or one of the forced ventilation units (1) has a central control device for controlling and/or regulating all forced ventilation units (1) of the forced ventilation system (10).

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