DE102018203077A1 - Building ventilation device - Google Patents

Abstract

The invention relates to a building ventilation device for a building (12), with at least one inlet channel (14) to an inlet of a fluid, in particular air, in particular into the building (12), with at least one outlet channel (16) to an outlet of the fluid in particular from the building (12), with at least one closure unit (18) for closing the inlet channel (14) and / or the outlet channel (16) and at least one control unit (20) to a control or regulation (30 ) at least one movement (22) of at least one closure element (24), in particular a bypass flap, the closure unit (18) in at least one, in particular defined, end position, in particular in a fully open position and / or in a completely closed position.
It is proposed that the control or regulating unit (20) is set up to move the at least one closure element (24) into intermediate positions, in particular different from end positions.

Description

State of the art

It is already a building ventilation device for a building, with at least one inlet channel to an inlet of a fluid, in particular air, in particular in the building, with at least one outlet channel to an outlet of the fluid, in particular from the building, with at least one closure unit for closing the Inlet channel and / or the outlet channel and with at least one control or regulating unit for controlling or regulating at least one movement of at least one closure element, in particular a bypass flap, the closure unit in at least one, in particular defined, end position, in particular in a fully open position and / or in a completely closed position, has been proposed.

Disclosure of the invention

The invention relates to a building ventilation device for a building, with at least one inlet channel to an inlet of a fluid, in particular air, in particular into the building, with at least one outlet channel to an outlet of the fluid, in particular from the building, with at least one closure unit to one Closing the inlet channel and / or the outlet channel and with at least one control or regulating unit for controlling or regulating at least one movement of at least one closure element, in particular a bypass flap, the closure unit in at least one, in particular defined, end position, in particular in a fully open position and / or in a completely closed position, the closure element.

It is proposed that the control or regulation unit is set up to move the at least one closure element into intermediate positions, in particular different from end positions. A "building ventilation device" is to be understood in particular as a device for exchanging a fluid in a building. In particular, the term "building" is representative of a structurally separated area, in particular for the entire building and / or separate substructures of the building, for example, floors or rooms. Preferably, the fluid is air, in particular a breathable gas mixture. Preferably, the replacement of the fluid serves to alter a fluid composition within the building, for example to alter a water content, a carbon dioxide content and / or an oxygen content of the fluid in the building. Preferably, the fluid in the building is discharged via the outlet channel. Preferably, a fluid, in particular with a desired fluid composition, is led into the building via the inlet channel. Preferably, the outlet channel and / or the inlet channel pipe, manhole, hose and / or other, to those skilled appear reasonable sense fluid guide elements. It is also conceivable that the outlet channel and the inlet channel are integrally formed, in particular identically. In particular, in a further embodiment of the building ventilation device, the outlet channel and the inlet channel are to be regarded as two functions of the same component.

A "closure unit" should in particular be understood to mean a unit which at least partially, preferably substantially completely, blocks a fluid flow of the fluid flowing into a fluid guiding element of the building ventilation device, in particular into the inlet channel and / or into the outlet channel in at least one operating state of the closure unit , By the fact that "a fluid flow of the fluid flowing in a fluid guiding element is substantially completely blocked", it should be understood that at least one point of the fluid guiding element has a cross sectional area of an interior of the fluid guiding element, in particular at least substantially perpendicular to a longitudinal axis of the fluid guiding element from the closure unit, in particular a closure element of the closure unit, is filled to at least 90%, preferably more than 95%, more preferably more than 99.5%. In particular, a fluid guide element which substantially completely blocks a fluid flow of the fluid flowing into the fluid guide element is substantially completely closed. The term "substantially perpendicular" is intended in particular to define an orientation of a direction relative to a reference direction, the direction and the reference direction, in particular in one plane, including an angle of 90 ° and the angle a maximum deviation of in particular less than 8 ° , Advantageously less than 5 ° and particularly advantageously less than 2 °. The blocking unit preferably has at least one movably mounted closure element for blocking a fluid guidance element, in particular the inlet channel and / or the outlet channel, which projects into the interior of the fluid guidance element and / or is movably mounted in the interior of the fluid guidance element, in particular in at least one operating state of the closure unit is. It is also conceivable that the closure element is designed as a switchable membrane element and / or as a filter element, in particular its fluid permeability due to an applied electrical variable, in particular an electrical Voltage and / or an electric current, and / or changed due to its temperature. The closure unit preferably has at least one movement unit for a movement of the closure element, in particular into the interior, out of the interior and / or inside the interior of the fluid guidance element, in particular the inlet channel and / or the outlet channel. For example, the movement unit is designed as an electric motor unit and / or as an actuator unit. It is also conceivable that the movement unit, in particular in addition, has an actuating element for a manually executable movement of the closure element. Preferably, the closure element is designed as a valve, in particular as a throttle valve. Particularly preferably, the closure element is designed as a bypass flap, in particular for a variation of a maximum flow cross-sectional size of the fluid guide element, in particular a formed as a bypass of the inlet channel and / or the outlet channel fluid guide element.

A "control or regulating unit" is to be understood as meaning in particular a unit having at least one control electronics. By "control electronics" is meant in particular a unit with a processor unit and with a memory unit and with an operating program stored in the memory unit. Preferably, the control or regulating unit is provided to move the closure element, in particular by means of the movement unit. Preferably, the control or regulating unit is provided to transfer the closure element in at least two different positions and in particular to hold the closure element in these positions. Preferably moves, in particular holds, the control or regulating unit, the closure element at least in one, in particular in two, defined end positions of the closure element. Preferably, a defined end position is formed as a completely closed position or as a completely open position of the closure element. A "completely closed position" is to be understood, in particular, as a position of the closure element which essentially completely closes the fluid guidance element, in particular the outlet channel and / or the inlet channel, by the closure element. A "completely open position" is to be understood in particular as a position of the closure element in which the closure element has a cross-sectional area of the interior of the fluid guidance element, in particular the outlet channel and / or the inlet channel, viewed at least substantially perpendicular to a longitudinal axis of the fluid guidance element along the longitudinal axis of the guide element by at least less than 10%, preferably less than 5% fills.

The defined end positions of the closure element preferably define a maximum movement span of the closure element relative to the fluid guidance element, in particular within the interior of the fluid guidance element. Preferably, the control or regulating unit is provided, in particular by means of the movement unit, to move the closure element in at least one intermediate position between the defined end positions, in particular to hold in at least one intermediate position between the defined end positions. Preferably, the control or regulating unit, in particular by means of the movement unit, is provided to move the closure element into a plurality of, in particular stepless, adjustable intermediate positions. Preferably, between, in particular infinitely, adjustable intermediate positions during a rotational movement of the closure element at least less than 15 °, preferably less than 10 °, more preferably less than 5 ° and / or in a translational movement of the closure element at least less than 15%, preferably less than 10%, the maximum range of motion.

The inventive design of the building ventilation device, a fluid flow through a fluid guide element, in particular by the inlet channel, the outlet channel and / or a bypass of the inlet channel and / or the outlet channel, on the basis of the closure unit advantageously adjustable, in particular continuously adjustable, are designed. In particular, it is advantageous to regulate a transport associated with the fluid flow, for example heat, moisture and / or oxygen. In particular, passive cooling of the building can advantageously be made flexible by exchanging the fluid. In particular, overheating of the building can advantageously be kept low.

It is further proposed that the building ventilation device comprises at least one sensor unit for detecting a fluid state variable of the fluid flowing through the inlet channel and / or the outlet channel for controlling or regulating a degree of closure of the inlet channel and / or the outlet channel defined by the intermediate positions of the closure element on the basis of the detected fluid state variable. A "fluid state variable" is to be understood as meaning in particular a, in particular physical, variable or code number which describes and / or characterizes a state of a fluid. Preferably, the fluid state quantity is formed as a temperature. It is also conceivable that the fluid state variable is formed as pressure, as flow number, as volume flow and / or as composition, in particular as moisture content, carbon dioxide content and / or oxygen content. Preferably, the Sensor unit at least one sensor element for detecting the fluid state variable, in particular the temperature of the inlet channel leaving, in particular flowing into the building, fluid. It is also conceivable for the sensor unit, in particular additionally, to be a sensor element for detecting a fluid state variable of a fluid flowing into the inlet channel, in particular of a fluid surrounding the building, and / or a sensor element for detecting a fluid state variable of an inflowing into the outlet channel, in particular the building leaving fluid. Preferably, the control or regulating unit is provided to control or regulate the movement of the closure element, in particular into an intermediate position, depending on the detected fluid state variable. Preferably, the control or regulating unit is provided to control or regulate the degree of closure of a fluid guiding element, in particular of the inlet channel and / or the outlet channel. A "degree of closure of a fluid guiding element" is to be understood in particular as the area projected by the closing element along a longitudinal axis of the fluid guiding element, in particular relative to a cross section area of an interior of the fluid guiding element, in particular of the inlet channel and / or the outlet channel, which is substantially perpendicular to the longitudinal axis. Preferably, the degree of closure of the fluid guiding element is defined by the positions, in particular the intermediate positions and / or the defined end positions of the closure element. By means of the configuration according to the invention, a fluid flow through a fluid guiding element, in particular through the inlet channel, the outlet channel and / or a bypass of the inlet channel and / or the outlet channel, can advantageously be adjusted on the basis of the closure unit as a function of a fluid state variable, in particular of a temperature of the fluid flow , Advantageously, a fluid flow entering the building, which has a certain value of the fluid state quantity, can be regulated.

It is also proposed that the inlet channel and / or the outlet channel have / has at least two fluid-technically parallel partial sections, of which at least one can be gradually closed by the closure element. By "fluidly parallel partial sections" should / should be understood in particular two separate trained fluid guide elements and / or a fluid guide element with at least one arranged in the interior of the fluid guide element separating element, in particular a switch, which / which in particular a fluid along two different paths from the same starting point , in particular from outside the building, and / or towards the same destination point, in particular into the building, leads / leads. Preferably, the inlet channel and / or the outlet channel have / has a branching into the fluid-technically parallel partial sections and / or a merging of the fluid-technically parallel partial sections. It is also conceivable for the inlet channel and / or the outlet channel to have at least two fluidically parallel fluid guide elements, which are designed to be fluidically separated, in particular each have their own inlet opening and / or outlet opening, in particular over an entire guide path of the outlet channel and / or the inlet channel , Preferably, at least one of the sections is gradually closed by the closure element. By "gradually closable" is to be understood in particular that the degree of closure, in particular via the intermediate positions of the closure element, at least in stages, preferably continuously, is adjustable. In a further embodiment of the device according to the invention, it is conceivable that at least two fluidic parallel partial sections are gradually, in particular independently, closed. It is also conceivable in particular for a degree of closure of the one section to be arranged inversely to the degree of closure of the other section, for example due to the construction via a three-way valve and / or control technology. Preferably, at least one partial section leads through a manipulation unit to a change in the fluid state variable of the fluid flowing through the partial section. Preferably, the manipulation unit is designed as a heat exchanger unit to a change in the temperature of the fluid flowing through the subsection. It is also conceivable that the manipulation unit is designed as an enrichment and / or filter unit for a change of a fluid composition, for example for a change of a water content. Due to the configuration according to the invention, it is advantageously possible to control or regulate a division, in particular a division ratio, of a fluid flow onto the two subsections. Alternatively or additionally, a mixture, in particular a mixing ratio, of the fluid streams flowing through the subsections can be advantageously controlled or regulated. In particular, the fluid state quantity, in particular the temperature, of the fluid leaving the inlet channel and / or the outlet channel may be advantageously regulated via the distribution ratio and / or the mixing ratio.

In addition, it is proposed that the building ventilation device comprise at least one sensor unit with at least one safety sensor element, in particular a dew point monitor, for determining a safety threshold value of a fluid state variable, in particular a temperature threshold value of a minimum permissible temperature of the fluid leaving the inlet channel. Under a "safety sensor element" is intended In particular, a sensor can be understood, which generates at least one qualitative, preferably quantitative, measurement signal with respect to an operating condition and / or an environmental condition, which in particular can lead to damage to the building ventilation device and / or the building. In particular, the safety sensor element generates a measuring signal when it exceeds or falls below a, in particular internal, threshold value. Preferably, the at least one safety sensor element is designed as a dew point monitor. The safety sensor element, in particular designed as a dew point monitor, is preferably arranged on an outer wall of the inlet channel, in particular in direct contact with the outer wall. The safety sensor element, which is designed in particular as a dew point monitor, is preferably arranged on the side of the inlet channel facing the building, in particular projecting into the building. Preferably, the safety sensor element, in particular designed as a dew point monitor, monitors an air humidity and / or a dew formation on the outer wall of the inlet channel. The safety sensor element, which is designed in particular as a dew point monitor, preferably generates a measuring signal at least when a threshold value for the air humidity is exceeded and / or when dewing is detected on the outer wall of the outlet channel. Preferably, the control or computing unit is provided to determine a safety threshold value for the fluid state variable, in particular a temperature threshold value, based on the measurement signal generated by the safety sensor element. The control or computing unit preferably generates a control variable for controlling or regulating the closure element as a function of the safety threshold value and of a current value of the fluid state variable detected by means of the sensor unit. The configuration according to the invention advantageously makes it possible to adapt a control or regulation of the closure unit to operating conditions or environmental conditions. In particular, damage to the building ventilation device and / or the building can be avoided.

At least one closure element of a closure unit for closing an inlet channel and / or an outlet channel of the building ventilation device in at least one method step by means of a control or regulation unit of the building ventilation device in a method for operating a, in particular inventive building ventilation device , In particular, from end positions different, intermediate positions is moved. Preferably, in at least one method step, a fluid state variable of the fluid flowing through the inlet channel and / or the outlet channel is detected by means of a sensor unit of the building ventilation device. Preferably, in at least one method step, the detected fluid state quantity is processed to control or regulate the movement of the closure element by means of the control unit. Preferably, in at least one method step, a degree of closure of the inlet channel and / or of the outlet channel is set by means of the control or regulating unit on the basis of the detected fluid state variable. In particular, in at least one method step, a degree of closure of one of at least two fluid-technically parallel subsections of the outlet channel and / or of the inlet channel is set by means of the control or regulating unit. Preferably, a safety threshold value of the fluid state variable, in particular a temperature threshold value of a minimum permissible temperature, of the fluid leaving the inlet channel is determined in at least one method section by means of a safety sensor element of the sensor unit. The inventive configuration of the method advantageously makes it possible to set a fluid flow through a fluid guiding element, in particular through the inlet channel, the outlet channel and / or a bypass of the inlet channel and / or the outlet channel, advantageously, in particular steplessly, by means of the closure unit.

It is also proposed that, in at least one method step, a movement of the at least one closure element, in particular into the intermediate positions, be continuously controlled or regulated as a function of a fluid state variable by means of the control or regulation unit of the building ventilation device. By "continuously controlling or regulating a movement of an element" it should be understood, in particular, that a position of the element is varied at least at regular intervals, preferably in real time, in particular to a continuous movement of the closure element into various intermediate positions. By "at regular intervals" should be understood in particular at least once within a given time frame. Additionally or alternatively, a change of an intermediate position of the closure element is triggered by a change in the detected fluid state quantity. In a further embodiment, it is also conceivable that the control or regulating unit and / or a sensor unit of the building ventilation device for detecting the fluid state variable between two changes and / or two detections of the intermediate positions at least one, in particular adjustable, dead time / has, to a premature Wear, for example, by a flutter, to avoid the closure element due to short-term fluctuations in fluid state size. Preferably, / is a distance traveled by the movement and / or an angle traversed by the movement between two intermediate positions, dependent on a value of the fluid state variable, in particular depending on a deviation of the fluid state variable from a desired value. By means of the configuration according to the invention, a fluid flow through a fluid guiding element, in particular through the inlet channel, the outlet channel and / or a bypass of the inlet channel and / or the outlet channel, can advantageously be adjusted in a timely and / or advantageous nuanced manner to fluctuations in the fluid state variable on the basis of the closure unit.

It is also proposed that in at least one method step, a fluid state variable, in particular a temperature, of the fluid leaving the inlet channel is controlled or regulated on the basis of a safety threshold value determined by means of a safety sensor element, in particular a dew point monitor. Preferably, in at least one method step by means of the safety sensor element, an operating condition and / or ambient condition, in particular dependent on the fluid state variable, is detected. Preferably, in at least one method step, a humidity and / or dew formation on an outer wall of the outlet channel is detected by means of a safety sensor element designed as a dew point monitor, in particular in combination with a temperature of the outer wall of the outlet channel. Preferably, in at least one method step, based on a signal generated by the safety sensor element, a safety threshold value, in particular a dew point temperature, for the fluid state variable, in particular the temperature of the fluid leaving the inlet channel, is determined. Preferably, exceeding and / or falling below the safety threshold triggers a movement of the closure element, in particular into an intermediate position. Preferably, the movement of the closure element is intended to change the fluid state quantity, in particular via a mixing ratio and / or a distribution ratio of the fluid flowing through the inlet channel, in particular to change the operating condition and / or ambient condition. Particularly preferably, the fluid state variable is controlled or regulated in at least one method step by means of the movement of the closure element. Preferably, the determined safety threshold value serves in at least one method step as a setpoint for the control or regulation of the fluid state variable. In particular, it is also conceivable that the desired value deviates from the safety threshold by a safety factor. Preferably, the fluid state quantity is controlled as the target value at least in a transition region between the fully opened position and the fully closed position of the closure element by means of the safety threshold value. In particular, the closure element is moved to the fully open and / or fully closed positions when the fluid state quantity of fluid entering the inlet channel reaches the safety threshold. As a result of the configuration according to the invention, the fluid state variable, in particular of the fluid leaving the inlet channel, can advantageously be adjusted by means of the control or regulation of the closure element. In particular, the fluid state variable can advantageously be kept at a, in particular still permissible, extreme value. Advantageously, for example, a minimum, in particular taubildung avoiding, temperature of the inlet channel leaving fluid can be adjusted. In particular, a temperature of the fluid flowing into the inlet channel can be specifically adapted, in particular increased. In particular, an allowable temperature range of a fluid flowing into the inlet channel can be made advantageously wide for passive cooling of the building with the building ventilation device; in particular, the permissible temperature ranges can advantageously comprise a region below the dew point temperature.

Furthermore, it is proposed that in at least one method step, a fluid state variable, in particular a temperature, of the fluid leaving the inlet channel is controlled or regulated on the basis of a user threshold determined by means of a user input. Preferably, in at least one method step, a user threshold, in particular a maximum and / or a minimum permissible value, is requested by means of a user input for the fluid state variable leaving the inlet channel. Preferably, exceeding and / or undershooting the user threshold triggers a movement of the closure element, in particular into an intermediate position. Preferably, the movement of the closure element is intended to change the fluid state quantity, in particular via a mixing ratio and / or a distribution ratio of the fluid flowing through the inlet channel, in particular to change the operating condition and / or ambient condition. Particularly preferably, the fluid state variable is controlled or regulated in at least one method step by means of the movement of the closure element. Preferably, the determined user threshold value serves in at least one method step as a desired value for the control or regulation of the fluid state variable. Preferably, the fluid state quantity is controlled as the target value at least in a transition region between the fully open position and the fully closed position of the closure element by means of the user threshold value. In particular, the closure element is moved to the fully open and / or the fully closed position when the fluid state quantity of the in the Inlet channel inflowing fluid reaches the user threshold. As a result of the configuration according to the invention, the fluid state variable, in particular of the fluid leaving the inlet channel, can advantageously be adjusted by means of the control or regulation of the closure element. In particular, the fluid state variable can advantageously be kept at a, in particular still permissible, extreme value. Advantageously, for example, a minimum, in particular of the user still perceived as pleasant, in particular a draft-avoiding temperature of the inlet channel leaving fluid can be adjusted. In particular, a temperature of the fluid flowing into the inlet channel can be specifically adapted, in particular increased. In particular, an allowable temperature range of a fluid flowing into the inlet channel can be made advantageously wide for passive cooling of the building with the building ventilation device; in particular, the permissible temperature range can advantageously comprise a region below a temperature causing drafts.

In addition, it is proposed that, in at least one method step, a maximum threshold value, in particular a maximum temperature threshold value, be determined from at least two determined threshold values, in particular temperature threshold values. Preferably, in at least one method step, a maximum threshold value is determined at least from the user threshold value and the security threshold value. Preferably, the fluid state quantity is controlled or regulated in at least one method step on the basis of the largest threshold value. In particular, the largest threshold is determined at least at regular intervals. The configuration according to the invention advantageously ensures that the fluid state variable of the fluid leaving the inlet channel is maintained at a simultaneously safe and user-adapted value.

It is also proposed that, in at least one method step, a step size of a change in a safety threshold value, in particular a temperature threshold value, be selected for the fluid leaving the inlet channel as a function of a measurement signal detected by means of a safety sensor element. Preferably, in at least one method step, the safety threshold value for the fluid state variable of the fluid leaving the inlet channel is determined on the basis of the measurement signal. Preferably, the safety threshold is adjusted at least at regular intervals based on a current measurement signal. The measurement signal preferably assumes at least two different values, in particular depending on an internal threshold value of the safety sensor element. In particular, it is also conceivable that the generation of the measurement signal is dependent on the internal threshold value, so that, for example, a value is coded by the absence and / or occurrence of a measurement signal. In particular, the threshold value separates a safe area of an environmental condition and / or operating condition from a harmful area, in particular for the building and / or the building ventilation device, an environmental condition and / or operating condition. The safety threshold value is preferably reduced at least at regular intervals as a function of the value of the measurement signal. The safety threshold value is preferably increased at least at regular intervals as a function of the value of the measurement signal. Preferably, the distances between two elevations are different than the distances between two decreases. In particular, the distances between two adjustments are shorter if the measurement signal indicates the harmful region of the environmental condition and / or the operating condition than if the measurement signal indicates the safe range of the environmental condition and / or the operating condition. Alternatively or additionally, a value by which the safety threshold is increased and / or decreased, depending on the value of the measurement signal. In particular, the value by which the safety threshold is increased and / or decreased during adaptation is higher when the measurement signal indicates the harmful region of the environmental condition and / or the operating condition than if the measurement signal is the safe region of the environmental condition and / or the operating condition displays. By virtue of the embodiment according to the invention, the safety threshold value can advantageously be determined flexibly and / or site-specifically. In particular, the safety threshold can advantageously be adapted to fluctuations in operating conditions and / or ambient conditions.

The building ventilation device according to the invention and / or the inventive method should / should not be limited to the application and embodiment described above. In particular, the building ventilation device according to the invention and / or the method according to the invention can have a number differing from a number of individual elements, components and units as well as method steps described herein for fulfilling a mode of operation described herein. In addition, in the value ranges indicated in this disclosure, values lying within the stated limits are also to be disclosed as disclosed and used as desired.

list of figures

Further advantages emerge from the following description of the drawing. In the drawings an embodiment of the invention is shown. The drawing, the description and the claims contain numerous features in combination. The person skilled in the art will expediently also consider the features individually and combine them into meaningful further combinations.

• 1 eine schematische Darstellung der erfindungsgemäßen Gebäudelüftungsvorrichtung,
• 2 ein Flussdiagramm eines erfindungsgemäßen Verfahrens und
• 3 ein Zustandsdiagramm des erfindungsgemäßen Verfahrens.

Show it:

• 1 a schematic representation of the building ventilation device according to the invention,
• 2 a flow chart of a method according to the invention and
• 3 a state diagram of the method according to the invention.

Description of the embodiment

1 shows a schematic representation of a building ventilation device 10 for a, in particular sketchy hinted, building 12 , The building ventilation device 10 includes at least one inlet channel 14 to an inlet of a fluid, in particular air, in particular in the building 12 , The inlet channel is preferred 14 provided air from one of the building 12 surrounding environment in the building 12 to lead. The building ventilation device 10 includes at least one outlet channel 16 to an outlet of the fluid, especially from the building 12 , The outlet channel is preferred 16 provided air from the building 12 in the building 12 to direct surrounding environment. The building ventilation device 10a preferably comprises at least one housing 50 , in particular the inlet channel 14 and / or the outlet channel 16 surrounds. The building ventilation device 10 includes at least one closure unit eighteen to a closure of the inlet channel 14 and / or the outlet channel 16 , The building ventilation device 10 includes at least one control unit 20 to a control or regulation 30 at least one movement 22 at least one closure element 24 , in particular a bypass flap, the closure unit eighteen in at least one, in particular defined, end position, in particular in a completely open position and / or in a completely closed position. The control unit 20 is adapted to the at least one closure element 24 in, in particular, from end positions different, intermediate positions to move. Preferably, the closure element 24 designed as a throttle valve. Preferably, the controlled or controlled movement 22 the closure element 24 as a rotational movement about one to a longitudinal axis of the inlet channel 14 essentially vertical axis of rotation 52 educated.

The inlet channel 14 and / or the outlet channel 16 have at least two fluidly parallel sections 32 . 34 on, of which at least one by the closure element 24 is gradually closed. Preferably, the inlet channel 14 a branch 54 in the two fluid-technically parallel sections 32 . 34 on. Preferably, the inlet channel 14 a merge 56 the two fluidly parallel section 32 . 34 on. Preferably, at one of the sections 32 . 34 a manipulation unit 58 arranged. Preferably, one of the two subsections 32 . 34 as a bypass 60 , in particular for bypassing the manipulation unit 58 educated. Preferably, the closure element 24 to a gradual closure of the bypass 60 intended. In particular, the closure element 24 within the bypass 60 arranged. Preferably, the control unit is 20 by a control or regulation 30 the movement 22 the closure element 24 provided a division of a fluid flow 51 at the junction 54 and / or a mixing ratio of the fluid flows through the sections 32 . 34 at the merger 56 to regulate. Preferably, the manipulation unit 58 as a heat transfer unit to an exchange of heat with the fluid in one of the sections 32 . 34 educated. Preferably, the manipulation unit 58 as a countercurrent layer heat exchanger, as a plate heat exchanger, as a spiral heat exchanger, as a tube heat exchanger and / or as another, the skilled person appear useful unit for transferring heat. Preferably, the manipulation unit exchanges 58 Heat energy between the fluid in the outlet channel 16 and the fluid in the inlet channel 14 , in particular the fluid in one of the sections 32 . 34 , out. Preferably, the manipulation unit serves 58 for heat recovery, in particular for preheating a through the inlet channel 14 flowing fluid, in particular by a transfer of heat from that through the outlet channel 16 flowing fluid to the through the inlet channel 14 flowing fluid. In an alternative embodiment, it is also conceivable that the manipulation unit 58 as, in particular electrical, heating and / or cooling unit is formed.

Preferably, the control unit is 20 to an adjustment of at least one passive heat transfer operation 64 and / or an active heat transfer operation 62 by means of the manipulation unit 58 intended. In particular, the closure element is located 24 during the active heat transfer operation 62 in the completely closed position. In particular, the fluid becomes during the active heat transfer operation 62 through the manipulation unit 58 directed. Preferably, the closure element is located 24 during the passive heat transfer operation 64 in the fully open position. In particular, the fluid is during the passive Heat transfer operation 64 over the bypass 60 directed. Preferably, the closure element is located 24 in a transitional mode 66 in at least one intermediate position. Preferably, in the transient mode 66 the fluid partially through the bypass 60 and partly by the manipulation unit 58 directed. Preferably, the control or regulation depends 30 the movement 22 the closure element 24 in an intermediate position of a fluid state quantity 28 of the fluid. The building ventilation device 10 includes at least one sensor unit 26 for detecting the fluid state quantity 28 of the inlet channel 14 and / or the outlet channel 16 flowing fluid, for control or regulation 30 one through the intermediate positions of the closure element 24 defined degree of closure of the inlet channel 14 and / or the outlet channel 16 based on the detected fluid state quantity 28 , In particular, the sensor unit comprises 26 at least one sensor element 68 for detecting the fluid state quantity 28 of the inlet channel 14 leaving fluid. Preferably, the sensor element 68 as a temperature sensor element for detecting a temperature of the inlet channel 14 leaving fluid formed. Additionally or alternatively, the sensor unit 26 further sensor elements 70 . 72 , in particular for detecting the fluid state quantity 28 in the inlet channel 14 and / or in the exhaust duct 16 inflowing fluid, on. The sensor unit 26 includes at least one safety sensor element 36 , in particular a dew point monitor, for determining a safety threshold 38 a fluid state quantity 28 , in particular a temperature threshold of a minimum allowable temperature of the inlet channel 14 leaving fluid. Preferably, this is, in particular designed as a dew point monitor, safety sensor element 36 on an exterior wall 74 of the intake channel 14 , in particular in direct contact with the outer wall 74 arranged. Preferably, this is, in particular designed as a dew point monitor, safety sensor element 36 on the building 12 facing, especially in the building 12 protruding side of the inlet channel 14 arranged. In particular, it is conceivable that the inlet channel 14 on the building 12 side facing a distribution device, in particular consisting of at least two fluidly parallel fluid guide elements, to a distribution of the fluid to different locations within the building 12 having. Preferably, at least the safety sensor element 36 and / or further safety sensor elements are arranged on an outer wall of the distribution device, in particular for determining a local, site-specific safety threshold value.

Preferably, the building ventilation device comprises 10 at least one fluid delivery unit 76 , Preferably, the fluid delivery unit 76 designed as an electrically operated fan or fan. Preferably, the fluid delivery unit comprises 76 , in particular for adjusting a volume flow of the through the inlet channel 14 flowing fluid, one in the inlet channel 14 arranged fluid conveying element 78 , It is also conceivable, in particular, that the subsections 32 . 34 each have at least one own, in particular independently controllable, fluid conveying element, in particular for supporting the manipulation unit 58 , Preferably, a, in particular identical, further fluid conveying element 80 to a setting of a volume flow through the outlet channel 16 flowing fluid in the outlet channel 16 arranged.

2 shows a flowchart of a method 40 for operating the building ventilation device 10 to a ventilation of the building 12 , In the process 40 is in at least one step by means of the control unit 20 the building ventilation device 10 at least the closure element 24 the locking unit eighteen to a closure of the inlet channel 14 and / or the outlet channel 16 the building ventilation device 10 in, in particular, from end positions different, intermediate positions moved. Preferably, the control unit generates 20 in at least one method step for control or regulation 30 the movement 22 a control variable 82 , In the process 40 In at least one method step, the movement 22 the at least one closure element 24 , in particular in the intermediate positions, continuously in dependence on a fluid state quantity 28 by means of the control unit 20 the building ventilation device 10 controlled or regulated. Preferably, in at least one method step, a fluid condition detection 84 for detecting the fluid state quantity 28 by means of the sensor unit 26 carried out. Preferably, in at least one method step, the temperature of, in particular the inlet channel 14 leaving, recorded fluids. In the process 40 In at least one process step, the fluid state quantity becomes 28 , in particular a temperature of the inlet channel 14 leaving fluid using a means of the safety sensor element 36 in particular a dew point monitor, determined safety threshold 38 controlled or regulated. Preferably, monitoring is performed in at least one method step 86 an operating condition and / or an environmental condition. In particular, during the monitoring 86 a measuring signal 48 , in particular at least at regular intervals generated. Preferably, in a processing step 88 from the measurement signal 48 the security threshold 38 certainly. In particular, by varying the fluid state size 28 a value of the fluid state quantity 28 determines at which the measurement signal 48 has a characteristic behavior, such as an exceeding a threshold, a sign change, a failure and / or appearance of the measurement signal 48 o. The like. Preferably, the measurement signal 48 at least the presence and / or absence of water on the outside wall 74 of the intake channel 14 and / or exceeding a threshold value of a relative humidity of the inlet channel 14 surrounding air inside the building 12 on. Preferably, based on the measurement signal 48 a temperature threshold for the inlet channel 14 leaving fluid determines, in which in particular a dew due to the humidity inside the building 12 starts. Preferably, at least at regular intervals after a detection of the measurement signal 48 the security threshold 38 customized. In the process 40 is in at least one process step, in particular in the processing step 88 , a step size of a change of a safety threshold 38 , in particular a temperature threshold, for the inlet channel 14 leaving fluid depending on one by means of the safety sensor element 36 detected measuring signal 48 selected. In the process 40 In at least one process step, a fluid state quantity becomes 28 , in particular a temperature of the inlet channel 14 leaving fluid by means of a user input 42 determined user threshold 44 controlled or regulated. In particular, the user input takes place 42 by means of a user interface 90 , Preferably, the user interface is 90 as, in particular wireless, communication unit to an input of the user threshold 44 via an external device, such as a remote control, a smartphone and / or tablet trained. But it is also conceivable that the user interface 90 via manual input elements, in particular keys, controllers and / or a touch screen, has. In the process 40 In at least one method step, at least two determined threshold values, in particular temperature threshold values, become a maximum threshold value 46 , in particular a maximum temperature threshold determined. In particular, a comparison is made in at least one method step 92 two determined thresholds, in particular the user threshold 44 and the security threshold 38 carried out. In particular, in the comparison 92 the threshold value determines the permissible value span of the fluid state variable 28 the most restrictive. Preferably, the largest temperature threshold is determined.

3 shows a state diagram of the method 40 , In particular, the method realizes 40 at least three different operating conditions for the building ventilation device 10 , Preferably, the method comprises 40 the active heat transfer operation 62 , in particular with the closure element 24 in the completely closed position. Preferably, the method comprises 40 the passive heat transfer operation 64 , in particular with the closure element 24 in the fully open position. Preferably, the method comprises 40 the transitional operation 66 , in particular with the closure element 24 in at least one of the intermediate positions. Preferably, the closure element becomes 24 in the transitional mode 66 continuously controlled or regulated. In particular, a position of the shutter member 24 in at least regular conditions to the fluid state quantity 28 , especially the temperature, adjusted. Preferably, a change of operation is based on the with the sensor unit 26 determined current fluid state quantity 28 , in particular the temperature determined. Preferably, the fluid state quantity becomes 28 in the inlet channel 14 inflowing fluid detected. This is referred to in particular as the outside temperature in the following. Preferably, the fluid state quantity becomes 28 in the exhaust duct 16 inflowing fluid detected. This is referred to below as internal temperature in particular. In particular, in at least one method step, a desired value for the fluid state variable 28 especially the temperature inside the building 12 queried. For example, the procedure triggers 40 an active transition change 94 from the active heat transfer operation 62 to the transitional operation 66 if the internal temperature is greater than or equal to the setpoint plus a buffer factor and the internal temperature is greater than or equal to the outdoor temperature and the outdoor temperature is greater than the maximum threshold 46 minus a heat recovery factor. Preferably, the buffering factor is intended to provide frequent toggling between the operating states due to short-term fluctuations in the fluid state quantity 28 to avoid, for example, the buffer factor is between 0.5 K and 1 K. Preferably, the heat recovery factor indicates a temperature difference to the one temperature, in particular completely, by the manipulation unit 58 flowing fluid, in particular maximum, is increased. For example, the heat recovery factor is between 3 K and 5 K. For example, the method changes 40 at an active change 96 from the passive heat transfer operation 64 and / or the transitional operation 66 in the active heat transfer mode 62 if the indoor temperature is less than the setpoint minus a buffer factor, or if the outdoor temperature is greater than the indoor temperature plus a buffer factor, or if the outdoor temperature is less than the largest threshold 46 minus a heat recovery factor. For example, the procedure triggers 40 a change of liability 98 from the active heat transfer operation 62 and / or from the transitional operation 66 to the passive heat transfer operation 64 if the indoor temperature is greater than or equal to a setpoint plus a buffer factor, and if the indoor temperature is greater than or equal to the outdoor temperature and if the outdoor temperature is greater than or equal to the largest threshold 46 plus is a buffer factor. For example, the procedure triggers 40 a passive transfer change 100 from the passive heat transfer operation 64 to the transitional operation 66 if the internal temperature is greater than or equal to the setpoint plus a buffer factor and if the internal temperature is greater than or equal to the outdoor temperature and if the outdoor temperature is less than the maximum threshold 46 plus is a buffer factor.

Claims (10)

Building ventilation device for a building (12), with at least one inlet channel (14) to an inlet of a fluid, in particular air, in particular into the building (12), with at least one outlet channel (16) to an outlet of the fluid, in particular from the building ( 12), with at least one closure unit (18) for closing the inlet channel (14) and / or the outlet channel (16) and with at least one control unit (20) to a control or regulation (30) of at least one movement (22 ) at least one closure element (24), in particular a bypass flap, the closure unit (18) in at least one, in particular defined, end position, in particular in a fully open position and / or in a completely closed position, characterized in that the control unit (20) is adapted to move the at least one closure element (24) in, in particular different from end positions, intermediate positions. Building ventilation device according to Claim 1 characterized by at least one sensor unit (26) for detecting a fluid state quantity (28) of the fluid flowing through the inlet channel (14) and / or the outlet channel (16) for controlling or regulating (30) one defined by the intermediate positions of the closure element (24) Degree of closure of the inlet channel (14) and / or the outlet channel (16) based on the detected fluid state quantity (28). Building ventilation device according to Claim 1 or 2 , characterized in that the inlet channel (14) and / or the outlet channel (16) has at least two fluidly parallel partial sections (32, 34), of which at least one is gradually closed by the closure element (24). Building ventilation device according to one of the preceding claims, characterized by at least one sensor unit (26) having at least one safety sensor element (36), in particular a dew point monitor, for determining a safety threshold value (38) of a fluid state variable (28), in particular a temperature threshold value of a minimum permissible temperature, the inlet channel (14) leaving fluid. Method for operating a building ventilation device (10), in particular according to one of the preceding claims, for ventilation of a building (12), wherein in at least one method step by means of a control unit (20) of the building ventilation device (10) at least one closure element (24) a closure unit (18) for closing an inlet channel (14) and / or an outlet channel (16) of the building ventilation device (10) in, in particular end positions different, intermediate positions is moved. Method according to Claim 5 , characterized in that in at least one method step, a movement (22) of the at least one closure element (24), in particular in the intermediate positions, continuously in response to a fluid state variable (28) by means of the control unit (20) of the building ventilation device (10) controlled or regulated. Method according to Claim 5 or 6 , characterized in that in at least one method step, a fluid state quantity (28), in particular a temperature, of the fluid leaving the inlet channel (14) is controlled or regulated by means of a safety threshold value (38) determined by means of a safety sensor element (36), in particular a dew point monitor. Method according to one of Claims 5 to 7 , characterized in that in at least one method step, a fluid state quantity (28), in particular a temperature, of the fluid leaving the inlet channel (14) is controlled or regulated by means of a user threshold (44) determined by means of a user input (42). Method according to one of Claims 5 to 8th , characterized in that in at least one method step from at least two determined threshold values, in particular temperature threshold values, a maximum threshold value (46), in particular a maximum temperature threshold value, is determined. Method according to one of Claims 5 to 9 , characterized in that in at least one method step, a step size of a change of a Sicherheitsschwellwerts (38), in particular a temperature threshold, for the inlet channel (14) leaving fluid depending on a by means of a safety sensor element (36) detected measurement signal (48) is selected.

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