BE1031086B1 - HYBRID VENTILATION SYSTEM AND METHOD FOR CONTROLLING SUCH VENTILATION SYSTEM - Google Patents

Abstract

The present invention concerns a method for ventilationally cooling a building. In particular, the invention provides a method for controlling a hybrid ventilation system comprising a hygienic ventilation system with a discharge flow passage extending between a discharge main connection and at least one discharge auxiliary connection and discharge flow control means for ensuring an air discharge flow from the at least one discharge auxiliary connection via the discharge flow passage to the drain main connection. This method comprises the step of controlling the discharge flow control means on the basis of a value measured by the sensor.

Description

1 BE2022/5974

HYBRID VENTILATION SYSTEM AND METHOD FOR IT

CONTROL OF SUCH A VENTILATION SYSTEM

The present invention concerns a method for controlling a hybrid ventilation system for ventilation cooling of a building. The present invention further relates to a hybrid ventilation system comprising a hygienic ventilation system as a central ventilation system and a decentralized air supply device.

The present invention further relates to a computer-implemented method, a data processing device, a computer program comprising instructions for causing a hygienic ventilation system to perform the steps of said method and a computer-readable storage means containing the computer program.

State of the art

Due to climate change, there are more and more periods of high temperatures, drought and lots of sun. This increases nuisance due to overheating in homes. A home overheats when the indoor temperature exceeds 25 degrees for a longer period of time. This heat lingers in the house for a long time, making it difficult to keep the house cool. The increasing need for cooling is partly due to the fact that houses are better insulated. In winter no heat is lost, but in summer no cold air comes in. Once a home is warm, it is difficult to lower the temperature.

This is particularly the case for apartments. There, the heat often also comes from neighboring apartments, so sun protection can help, but is not useful enough to control the temperature, so a solution must be found to remove existing heat from an apartment.

It is difficult to cool these homes. When working with district heating, active cooling solutions (e.g. air-water heat pumps) are difficult to use. Solutions with air conditioning (e.g. air-to-air heat pumps) have acoustics and sustainable energy supply as a challenge.

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A passive alternative is natural cooling with air by actively opening shutters (or windows), but because there are often not two facades free and/or there is no skylight, the flow rates achieved naturally are often limited, resulting in either large shutters are necessary or a limited cooling capacity is achieved.

A variant for natural cooling, without energy supply, is to mechanically evacuate the warm air from the home. As a result, natural solutions for cooling and hygienic, mechanical ventilation systems are installed side by side and there is no synergy between such systems in a home, with the risk of suboptimal air quality, less comfort and often poorer energy performance.

This problem is particularly acute in apartments due to the specific energy supplies, smaller dimensions and the collective nature of energy exchange with neighboring homes. But it is a general problem that applies to any type of home, especially when there is no natural draft through either cross ventilation or thermal draft.

Purpose of the invention

The present invention and its preferred embodiments aim to provide a solution for one or more of the aforementioned disadvantages. An aim of the invention may therefore be to provide a hybrid ventilation system that is also suitable for ventilating the same home.

A further object of the invention may therefore be to provide a method for controlling a hybrid ventilation system that is suitable for ventilated cooling of a home.

In particular, it may be an object of the invention to provide a hybrid ventilation system for hygienic ventilation and ventilation cooling of the same home during summer nights. Preferably with a limited influence on the acoustic behavior, price and/or power or use of the ventilation system.

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Description of the invention

This aim is achieved according to the invention with a method for ventilationally cooling a building that has the technical characteristics of one of the independent claims.

To this end, the present invention concerns a method for controlling hybrid ventilation comprising a hygienic ventilation system and a decentralized air supply device for supplying outside air via an opening in an outer wall of the building. The term “hygienic ventilation system” refers to the set of various components that ensure that the air in rooms of the building is refreshed in a controlled manner.

In particular, the invention provides a method for controlling a hybrid ventilation system comprising a hygienic ventilation system with a discharge flow passage extending between a discharge main connection and at least one discharge auxiliary connection and discharge flow control means for ensuring an air discharge flow from the at least one discharge auxiliary connection via the discharge flow passage to the drain main connection. The term “connection” refers to an open end to which an air duct may or may not be connected, e.g. an opening in the housing of a ventilation box or an end of an air duct. Such a hygienic ventilation system is described, for example, in NL 2014612 and NL 2022733, the contents of which are hereby incorporated by reference.

In a first aspect of the invention, which may occur in combination with the other aspects and embodiments of the invention described herein, the invention includes a method for controlling such a hybrid ventilation system comprising a sensor for measuring a parameter related to the supply flow of outside air through the decentralized air supply device. This method comprises the step of controlling the discharge flow control means on the basis of a value measured by the sensor.

By controlling the exhaust flow control means on the basis of a parameter related to the supply flow of outside air through the decentralized air supply device, using a sensor, the air exhaust can be effectively and efficiently coordinated with the air supply through the decentralized air supply device. In particular, it is because of this

4 BE2022/5974 allows the hygienic ventilation system to cool ventilation when the decentralized air supply device is activated or opened. Furthermore, this also allows the discharge flow to be matched to the decentralized supply flow. In an alternative operation, part of the exhaust flow, i.e. one or more of the zonal exhaust air flows related to the exhaust auxiliary connections, can also be matched to the decentralized supply flow.

In an embodiment, which may occur in combination with the other aspects and embodiments of the invention described herein, aforesaid method, further comprising the steps of: adjusting a ventilation condition of the hygienic ventilation system based on an input determined by the sensor measured value, and controlling the exhaust flow control means on the basis of one or more parameters related to the ventilation condition of the hygienic ventilation system. Adjusting a ventilation condition of the hygienic ventilation system based on a value measured by the sensor can include the following steps: setting a hygienic ventilation condition when the value measured by the sensor is related to a minimum supply flow rate of the decentralized air supply device, and setting a summer night ventilation condition when the value measured by the sensor is not related to an outdoor air supply flow rate that is different from the minimum supply flow rate of the decentralized air supply device. Preferably, the minimum supply flow of the decentralized air supply device is zero or negligible.

In an embodiment, which may occur in combination with the other aspects and embodiments of the invention described herein, this concerns a aforementioned method, wherein the value measured by the sensor is one or more of the following parameters: the indoor temperature, the outdoor temperature, CO, relative humidity and a position sensor. Preferably, one of the parameters is the temperature difference between the indoor and outdoor temperatures near the decentralized air supply device.

A first embodiment, which can occur in combination with the other aspects and embodiments of the invention described herein, concerns an aforementioned method, which comprises controlling the discharge flow control means on the basis of one or more parameters related to the ventilation condition of the hygienic ventilation system. controlling the exhaust flow control means in such a way that: when the hygienic ventilation system is in a hygienic ventilation condition, the air exhaust flow QeTa corresponds to a hygienic air exhaust flow Quyc related to the air quality in one or more rooms of the building, and when the hygienic ventilation system is in a summer night ventilation condition, for at least one of the exhaust auxiliary connections the (zonal) exhaust air flow rate corresponds to the sum of the (zonal) hygienic air exhaust flow rate and a (zonal) thermal flow rate. In other words, in the summer night ventilation condition, more air will flow through at least one of the exhaust auxiliary connections than is necessary to achieve the hygienic ventilation flow rates. The hygienic exhaust air flows will flow through the other exhaust auxiliary connections.

Preferably, the thermal flow rate is determined on the basis of the value measured by the sensor. In particular, the thermal flow rate corresponds to the supply flow rate of the outside air through the decentralized air supply device.

A second embodiment, which may occur in combination with the other aspects and embodiments of the invention described herein, concerns an aforesaid method, wherein the discharge flow control means are formed by a discharge blower for generating an air discharge flow from the discharge main connection via the discharge flow passage to the at least one discharge auxiliary connection, the method comprising the step of ensuring the air discharge flow by generating the air discharge flow with the discharge blower.

A third embodiment, which can occur in combination with the other aspects and embodiments of the invention described herein, concerns an aforementioned method, wherein the discharge flow control means are formed by one or more discharge control valves for regulating the air discharge flow rate of a generated air discharge flow that flows from the discharge main connection through the discharge flow passage to the at least one discharge auxiliary connection, the method further comprising the step of ensuring the discharge air flow by regulating the flow rate with the discharge control valves.

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In a second aspect of the invention, which may occur in combination with the other aspects and embodiments of the invention described herein, the invention includes a hybrid ventilation system for ventilating and ventilating a building, comprising a hygienic ventilation system for ventilating and ventilating a building configured to perform a said method, said hygienic ventilation system comprising an exhaust flow passage extending between a discharge main connection and at least one discharge auxiliary connection and exhaust flow control means for ensuring an exhaust air flow from the at least one discharge auxiliary connection through the exhaust flow passage to the discharge main connection, and a decentralized air supply device for supplying outside air through an opening in an outer wall of the building. The decentralized air supply device can supply the air passively, by passively supplying outside air into the building under the influence of a pressure difference between the outside and the inside of the building, or supply the air actively, using mechanical ventilation. The decentralized air supply device can be designed as an opening element, for example a window, door, sliding door, grille or in particular a summer night ventilation hatch.

In an embodiment, which may occur in combination with the other aspects and embodiments of the invention described herein, a said sanitary ventilation system comprising a sanitary ventilation device comprising a housing and a discharge flow passage extending between a discharge main connection and at least one discharge auxiliary connection and discharge flow control means for ensuring an air discharge flow from the at least one discharge auxiliary connection via the discharge flow passage to the discharge main connection are included.

In a fourth aspect of the invention, which may occur in combination with the other aspects and embodiments of the invention described herein, the invention includes a computer-implemented method for ventilating and fan cooling a building, comprising the steps of - receiving, by a processor, a signal related to the supply flow of a decentralized air supply device of a hybrid ventilation system according to any of the preceding claims 10-14,

7 BE2022/5974 - developing, by a processor, a signal for controlling the discharge flow control means of a hygienic ventilation system of the hybrid ventilation system in response to receiving the signal; - providing, by the processor, the signal to the hygienic ventilation system; and - controlling the hygienic ventilation system in response to the signal.

In a fifth aspect of the invention, which may occur in combination with the other aspects and embodiments of the invention described herein, the invention includes a computer-implemented method for ventilating and fan cooling a building, comprising the steps of - receiving, by a processor, a control signal related to the ventilation condition of a hygienic ventilation system of a hybrid ventilation system according to any of the preceding claims 10-14, - developing, by a processor, a control signal for controlling the decentralized air supply device of the hybrid ventilation system in response to receiving the control signal, - the processor providing the control signal to the decentralized air supply device; and - controlling the decentralized air supply device in response to the control signal.

In a sixth aspect of the invention, which may occur in combination with the other aspects and embodiments of the invention described herein, the invention includes a computer-implemented method for ventilating and fan cooling a building, comprising the steps of - developing, by a processor, a signal for controlling the exhaust flow control means of a hygienic ventilation system of the hybrid ventilation system in response to receiving the signal and of a control signal for controlling the decentralized air supply device of the hybrid ventilation system in response on receiving the control signal;

8 BE2022/5974 - providing, by the processor, the signal to the hygienic ventilation system and the control signal to the decentralized air supply device; and - controlling the hygienic ventilation system in response to the signal and the decentralized air supply device in response to the control signal.

In a seventh aspect of the invention, which may occur in combination with the other aspects and embodiments of the invention described herein, the invention includes a data processing apparatus comprising a processor configured to perform the steps of the foregoing method.

In an eighth aspect of the invention, which may occur in combination with the other aspects and embodiments of the invention described herein, the invention includes a computer program that includes instructions for causing said data processing apparatus to perform the steps of said method.

In a ninth aspect of the invention, which may occur in combination with the other aspects and embodiments of the invention described herein, the invention includes a computer-readable storage means containing a said computer program.

In a final aspect of the invention, which may occur in combination with the other aspects and embodiments of the invention described herein, the invention comprises a building, for example a house or apartment, with two or more rooms comprising a aforementioned hybrid ventilation system.

Brief description of the figures

The invention will be explained in more detail below with reference to an exemplary embodiment shown in the drawing.

Figure 1 shows a simplified section of a house according to a first embodiment of the present invention;

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Figure 2 shows a cross-section through the hygienic ventilation device shown in Figure 1;

Figure 3 shows a simplified cross-section of an apartment building according to a second embodiment of the present invention,

Figures 4 shows different flow rates of the hygienic ventilation device shown in Figure 1 during different states, and

Figures SA-SC show different forms of control of the hybrid ventilation system shown in figure 1.

Extensive description of the figures

The present invention will be described with respect to certain embodiments and with reference to certain drawings, but the invention is not limited thereto and is determined only by the claims. The drawings described are only schematic and non-limiting. In the drawings, the size of certain elements may be exaggerated and not drawn to scale for illustrative purposes. The dimensions and relative dimensions do not necessarily correspond to actual practical embodiments of the invention.

Furthermore, the terms first, second, third and the like are used in the description and in the claims to distinguish between similar elements and not necessarily to describe a sequential or chronological order.

The terms are interchangeable under appropriate circumstances and the embodiments of the invention may be practiced in sequences other than those described or illustrated herein.

In addition, the terms above, below, over, below and the like in the description and claims are used for illustrative purposes and not necessarily to describe relative positions. The terms so used are interchangeable under appropriate circumstances and the embodiments of the invention described herein may be employed in orientations other than those described or illustrated herein.

Furthermore, the various embodiments, although referred to as "preferred forms", should rather be regarded as examples in which the

10 BE2022/5974 invention can be implemented as a limitation of the scope of the invention.

The term “comprising” used in the claims should not be construed as being limited to the means or steps set forth below; the term does not exclude other elements or steps. The term should be interpreted as specifying the presence of the mentioned features, elements, steps or components referred to, but does not exclude the presence or addition of one or more other features, elements, steps or components, or groups thereof . The scope of the expression “a device comprising means A and

B” should therefore not be limited to devices that only consist of components A and

B exist. The meaning is that with respect to the present invention only components A and B of the device are listed, and the claim is further construed to also include equivalents of these components.

Fig. 1 shows a building 1a in the form of a home consisting of several rooms 11, 12, 21, 22 and a circulation area 30, for example a corridor, hall or landing, which allows access to the rooms. The building 1a shown in Figure 1 has several living areas in the form of rooms 11, 12, for example a living room or a bedroom, to which supply air, SUP, can be supplied via the supply auxiliary ducts (not shown). The building also has function spaces 1a in the form of rooms 21, 22, for example a toilet room, a bathroom or a kitchen, from which exhaust air, ETA, can be discharged via the exhaust auxiliary ducts 4, 5. Each of these auxiliary ducts 4, 5 is connected to an auxiliary connection 123-125 of a hygienic ventilation system 100. With one or more manifolds (not shown), multiple, similar auxiliary ducts can be simultaneously connected to one auxiliary connection. The building further comprises a discharge main duct 8 for discharge of exhaust air, EHA, from a discharge main connection 122 of the hygienic ventilation system 100.

The building 1a further comprises a decentralized air supply device in the form of a summer night ventilation hatch 200 for supplying outside air to one of the living areas. A summer night ventilation hatch is a ventilation hatch that ensures efficient cooling of the building according to the summer night ventilation principle, thanks to the supply of large ventilation flow rates. The summer night ventilation hatch 200 is typically equipped with a burglar-resistant, rain-resistant and/or insect-resistant external grille

11 BE2022/5974 in such a way that it can be opened without negative consequences. In particular, the summer night ventilation hatch 200 is designed to be opened on the basis of an external signal or to send a signal when opened manually, which signal can be received by the hygienic ventilation system 100 or a control system connected thereto. In response to receiving the signal, the hygienic ventilation system 100 can then generate a thermal flow rate QTrrrm by increasing the flow rate QrTta of exhausted return air ETA to increase the pressure difference across the summer night ventilation hatch 200. This allows the same cooling capacity (compared to natural ventilation) to be achieved with more freedom in the location and size of the summer night ventilation hatch 200. For example, a smaller summer night ventilation hatch in surface area and fewer or further spaced summer night ventilation hatches to obtain the same supply flow.

An embodiment of the hygienic ventilation system 100 is shown in figure 2. This hygienic ventilation system 100 has a housing indicated in its entirety by 101 with a discharge main connection 122 to which the discharge main duct 7 can be connected. At the other end of the housing are one or more discharge auxiliary connections 123-125, used three in the exemplary embodiment shown, and optionally one or more cooling auxiliary connections 160, used one in the exemplary embodiment shown, with a cooling auxiliary valve 162 for closing the cooling auxiliary connection 160. The exhaust plenum 120 extends between the discharge auxiliary connections 123 and the air discharge main connection 122. The discharge of air takes place by means of the blower 121, which is placed in the discharge plenum near the air discharge main connection 122.

In the basic version of the hygienic ventilation system 100, the air flows from the various ducts to the various rooms depending on the resistance, without any further adjustment options. In connection with offering the possibility of a desired distribution of the exhausted air, hygienic control valves 126-128 can be placed in the auxiliary connections. Each control valve can be housed in a cassette, which in turn is housed in a cassette chamber located at or behind the relevant air supply auxiliary connection. Each cassette can furthermore have a measuring system, which can, for example, have a sensor for measuring the CO? value of air, relative humidity, temperature and the like. On base

12 BE2022/5974 From measurements of this sensor, not only the hygienic ventilation system but also the summer night ventilation hatch can be controlled.

Fig. 3 shows a building 1b in the form of an apartment building consisting of several residential units with rooms 11-13, 21-26 and circulation areas (not shown), for example a corridor, hall or landing, which allow access to the rooms. Each residential unit shown in Figure 3 has living areas in the form of rooms 11-13, for example a living room or a bedroom, to which supply air, SUP, can be supplied via the supply auxiliary ducts 2. Return air, ETA, can also be discharged from function spaces in the form of rooms 21-26, for example a toilet room, a bathroom or a kitchen, through exhaust auxiliary ducts 4. Each of these auxiliary channels 2, 4, 5 is connected to a hygienic ventilation system in the form of a hygienic ventilation assembly 300a-300c. One or more manifolds (not shown) allow simultaneous connection of multiple, similar auxiliary ducts to one auxiliary connection. The building further comprises a supply main duct 6 for supply of outside air, ODA, to a supply connection of the hygienic ventilation assembly 300a-300c and a discharge main duct 7 for discharge of air, EHA, from a discharge connection of the hygienic ventilation assembly 3004-3000.

Each residential unit further comprises a decentralized air supply device in the form of a summer night ventilation hatch 201-203 for supplying outside air to one of the living areas. In particular, the summer night ventilation hatch 200 is designed to be opened on the basis of an external signal or to send a signal when opened manually, which signal can be received by the hygienic ventilation system or a control system connected to it. In response to receiving the signal, the hygienic ventilation system can then generate a thermal flow rate QTnerm by increasing the discharge flow rate Qera to increase the pressure difference across the summer night ventilation hatch 200 such that a smaller hatch can be used to obtain the same flow rate.

In the basic embodiment of the hygienic ventilation assembly 300a-300c, the collectively generated air flows through a central control valve 311, 312, 313; 321 and depending on the resistance in the various auxiliary channels 2, 4, 5 without further

13 BE2022/5974 possibility of control to the various rooms, or the air is extracted from them. In order to offer the possibility of a desired distribution of the supplied air, several control valves, zonal 322-323 or local 324-325, can be placed in the auxiliary connections or in the auxiliary ducts. Each control valve can be included in a cassette. Each cassette can furthermore have a measuring system, which can, for example, have a sensor for measuring the CO2 value of air, relative humidity, temperature and the like. A constant volume regulator 310, 320 can be provided between the central, zonal or local control valve 311-313, 321-325 and a collective air duct 8, 9 for limiting the maximum air flow through the air auxiliary ducts. In addition, a fire damper (not shown) can be provided between the constant volume controller 310, 320 and the collective air duct 8, 9.

The operation of the central hygienic ventilation system 100, 300a-300c is illustrated in figure 4. An internal or external control unit or processor 150 is arranged to control the discharge blower 121 or the one or more discharge control valves 320-325. The control of these elements will depend on the ventilation condition of the hygienic ventilation system. As is clearly evident from Figure 4, which shows the time course of the air exhaust flow rate QeTa in a hygienic ventilation condition I (left) and a summer night ventilation condition II (right).

In the hygienic ventilation condition, the hygienic ventilation system functions like a conventional demand-controlled ventilation system and the ventilation requirement is adjusted to the air quality between a minimum, set ventilation flow rate QsET, MN and a maximum, set ventilation flow rate Qser, max. The set ventilation flow rates

QsrT are determined based on the legal ventilation standards. The demand-driven ventilation flow Quyc can be controlled based on CO?, moisture, time (day and night as a 2-zone system) and possibly movement. The air exhaust flow QrTa will therefore fluctuate between QsET, MIN and QsET, max based on the air quality.

When transitioning to the summer night ventilation condition, the hygienic ventilation system will extract more air in order to achieve the desired supply flow rates with the summer night ventilation hatch 200-203. In figure 4, the exhaust air flow rate Qrrta will be maximized to a level above the set ventilation flow rate OsrT. max and thus use the excess capacity of the hygienic ventilation system to ventilate the building. This will make it

14 BE2022/5974 exhaust air flow rate QrTa corresponds to the sum of the hygienic, demand-driven ventilation flow rate Quyc and an additional thermal flow rate QrTHerRM.

In an alternative operation (not shown), one or more of the zonal exhaust air flow rates related to the exhaust auxiliary connections can also be maximized to a level above a maximum, set zonal ventilation flow rate, preferably up to the ventilation capacity of the auxiliary connection or an associated cooling auxiliary duct.

The operation of a hybrid ventilation system comprising the central hygienic ventilation system 100, a summer night ventilation hatch 200 and a sensor for measuring a parameter related to the supply flow of outside air through the decentralized air supply device is illustrated in figure 5. This sensor can be part of the summer night ventilation hatch. 200, the central hygienic ventilation system 100 (e.g. the sensor of a control valve) or an external sensor present in a room of the building. It is foreseeable that one or more elements of the hybrid ventilation system can be controlled based on measurements from one or more sensors, e.g. a combination of a sensor of the summer night ventilation hatch 200, a summer night ventilation hatch 200 of the hygienic ventilation system 100 and/or a room sensor.

Figure SA shows the reception by a processor 150 of a signal SoPENED related to the opening of the summer night ventilation hatch 200 and in response to this developing and transmitting a signal SvenT related to the ventilation cooling using the hygienic ventilation system 100, for example a signal to ventilation condition or a signal to adjust the exhaust air flow rate. The Sopexep signal can come from the summer night ventilation hatch 200 or an external sensor (not shown).

Figure SB shows the receipt by a processor 150 of a signal Soren related to changing the ventilation state of the hygienic ventilation system 100 to a summer night ventilation state and in response to this developing and transmitting a signal Soren related to the opening of the summer night ventilation hatch 200.

Figure SC shows the development and transmission of the signal SvenT and the development and transmission of a signal Soren. Here both parts are controlled by the processor 150 in response to an external action, i.e. not originating from the hybrid ventilation system, for example by the manual activation of a user.

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List of reference characters la, 1b. Building 2, 3. Supply auxiliary channel 4,5. Drainage auxiliary channel 6. Supply main channel 7. Discharge main channel 8. Collective supply channel 9. Collective exhaust channel 11-13. Living area 21-26. Function space 100. Hygienic ventilation device 101. Housing 110. Supply flow passage 111. Supply blower 112. Supply main connection 113-114. Supply auxiliary connection 120. Discharge flow passage 121. Discharge blower 122. Discharge main connection 123-125. Drain aid connection 126-128. Hygienic Flow Controller 150. Processor 160. Cooling auxiliary connection 162. Cooling auxiliary valve 200-203. Summer night ventilation hatch 300a-300c. Hygienic ventilation assembly 310. Constant supply volume controller 311-313. Supply control valve

17 BE2022/5974 320. Constant discharge volume controller 321-325. Exhaust control valve 400. Collective supply fan 500. Collective extract fan

ETA. Exhaust air from the home to the ventilation device

FHA. Exhaust air from the ventilation device to the outside

ODA. Supply air from outside to the ventilation device

SUP. Supply air from the ventilation device to the home

Claims (22)

18 BE2022/5974 Conclusions l. Method for controlling a hybrid ventilation system for ventilating and ventilating a building, said hybrid ventilation system comprising: - a hygienic ventilation system comprising an exhaust flow passage extending between a discharge main connection and at least one discharge auxiliary connection and discharge flow control means for ensuring an exhaust air flow from the at least one discharge auxiliary connection via the discharge flow passage to the discharge main connection, - a decentralized air supply device for supplying outside air through an opening in an outer facade of the building, and - a sensor for measuring a parameter related to the supply flow rate of outside air through the decentralized air supply device, the method comprising the step of controlling the discharge flow control means on the basis of a value measured by the sensor. 2. Method according to claim 1, the method further comprising the steps of: - adjusting a ventilation condition of the hygienic ventilation system on the basis of a value measured by the sensor, and - controlling the discharge flow control means on the basis of one or more parameters related to the ventilation condition of the hygienic ventilation system. 3. Method according to claim 2, wherein adjusting a ventilation condition of the hygienic ventilation system on the basis of a value measured by the sensor comprises: - setting a hygienic ventilation condition when the value measured by the sensor is related to a minimum supply flow rate of the decentralized air supply device, and - setting a summer night ventilation condition when the value measured by the sensor is not related to an outdoor air supply flow rate that is different from the minimum supply flow rate of the decentralized air supply device. 19 BE2022/5974 4. Method according to any of the preceding claims, wherein the value measured by the sensor is one or more of the following parameters: the indoor temperature, the outdoor temperature, CO2, relative humidity and a position sensor. 5. Method according to any of the preceding claims, wherein controlling the exhaust flow control means on the basis of one or more parameters related to the ventilation condition of the hygienic ventilation system comprises controlling the discharge flow control means such that: - when the hygienic ventilation system is in a hygienic ventilation condition is located, the exhaust air flow rate Qrrta corresponds to a hygienic exhaust air flow rate Quyc related to the air quality in one or more rooms of the building, - when the hygienic ventilation system is in a summer night ventilation condition, for at least one of the exhaust auxiliary connections the exhaust air flow rate Qera corresponds to the sum of the hygienic exhaust air flow rate Quyc and a thermal flow rate QrHerm. Method according to claim 5, wherein the thermal flow rate Qruerm is determined on the basis of the value measured by the sensor. 7. Method according to claim 6, wherein the thermal flow rate Qruerm corresponds to the supply flow rate of the outside air. 8. Method according to any of the preceding claims, wherein the discharge flow control means are formed by a discharge blower for generating an air discharge flow from the discharge main connection via the discharge flow passage to the at least one discharge auxiliary connection, the method comprising the step of ensuring the air discharge flow by generating the exhaust air flow with the exhaust blower. 9. Method according to any one of the preceding claims, wherein the discharge flow control means are formed by one or more discharge control valves for regulating the air discharge flow of a generated BE2022/5974 exhaust air flow flowing from the discharge main connection via the discharge flow passage to the at least one discharge auxiliary connection, the method further comprising the step of ensuring the exhaust air flow by controlling the flow rate with the discharge control valves. 10. Hybrid ventilation system for ventilating and ventilating a building, comprising a hygienic ventilation system for ventilating and ventilating a building, configured to perform a method according to any one of the preceding claims, said hygienic ventilation system comprising an exhaust flow passage extending extends between a discharge main connection and at least one discharge auxiliary connection and discharge flow control means for ensuring an air discharge flow from the at least one discharge auxiliary connection via the discharge flow passage to the discharge main connection, and a decentralized air supply device for supplying outside air via an opening in an outer wall of the building. 11. Hybrid ventilation system for ventilating and ventilating a building, comprising a hygienic ventilation system for ventilating and ventilating a building, configured to carry out a method according to any one of the preceding claims, said hygienic ventilation device comprising a housing incorporating a discharge flow passage extending between a discharge main connection and at least one discharge auxiliary connection and discharge flow control means for ensuring an air discharge flow from the at least one discharge auxiliary connection via the discharge flow passage to the discharge main connection, and a decentralized air supply device for supplying outside air via an opening in an exterior facade of the building. 12. Hybrid ventilation system according to claim 10 or 11, wherein the decentralized air supply device is designed for passively supplying outside air into the building under the influence of a pressure difference between the exterior and the interior of the building. 21 BE2022/5974 13. Hybrid ventilation system according to claim 12, wherein the decentralized air supply device is formed by a summer night ventilation hatch. 14. Building comprising a hybrid ventilation system according to any of the preceding claims 10-13. 15. Computer-implemented method for ventilating and ventilating a building, comprising the steps of: - receiving, by a processor, a signal related to the supply flow of a decentralized air supply device of a hybrid ventilation system according to any of the preceding claims 10-14, - developing, by a processor, a signal for controlling the discharge flow control means of a hygienic ventilation system of the hybrid ventilation system in response to receiving the signal, - providing, by the processor, the signal to the hygienic ventilation system; and - controlling the hygienic ventilation system in response to the signal. 16. Computer-implemented method according to claim 15, wherein the signal comes from a sensor for measuring a parameter related to the supply flow of outside air through the decentralized air supply device. 17. Computer-implemented method according to claim 16, wherein the decentralized air supply device is designed as a summer night ventilation hatch and the sensor is designed as a position sensor of the summer night ventilation hatch, wherein the position sensor is designed to generate the signal when the summer night ventilation hatch is opened. 18. Computer-implemented method for ventilating and ventilating a building, comprising the steps of: - receiving, by a processor, a control signal related to the ventilation condition of a hygienic ventilation system of a hybrid ventilation system according to any of the preceding claims 10-14, 22 BE2022/5974 - developing, by a processor, a control signal for controlling the decentralized air supply device of the hybrid ventilation system in response to receiving the control signal; - providing, by the processor, the control signal to the decentralized air supply device; and - controlling the decentralized air supply device in response to the control signal. 19. Computer-implemented method for ventilating and ventilating a building, comprising the steps of: - developing, by a processor, a signal for controlling the exhaust flow control means of a hygienic ventilation system of the hybrid ventilation system in response to receiving the signal and a control signal for controlling the decentralized air supply device of the hybrid ventilation system in response to receiving the control signal; - providing, by the processor, the signal to the hygienic ventilation system and the control signal to the decentralized air supply device; and - controlling the hygienic ventilation system in response to the signal and the decentralized air supply device in response to the control signal. 20. Data processing device comprising a processor configured to perform the steps of the method according to any of the preceding claims 15-19. 21. A computer program that comprises instructions for causing the data processing device according to claim 20 to perform the steps of the method according to any of the preceding claims 15-19. A computer-readable storage medium containing the computer program of claim 21.