WO2024099490A1

WO2024099490A1 - Vehicle seat ventilator

Info

Publication number: WO2024099490A1
Application number: PCT/DE2023/000134
Authority: WO
Inventors: Stefan Stöwe
Original assignee: Gentherm Gmbh
Priority date: 2022-11-10
Filing date: 2023-10-24
Publication date: 2024-05-16
Also published as: DE102022004186A1

Abstract

The invention relates to an air conditioning device (10) for ventilating a vehicle seat (100), with at least one air conveying device (14) which is configured to convey air through an air-permeable seat cushion (102) of the vehicle seat (100), and with at least one electronic air flow monitoring unit (12) which is configured to detect at least one parameter relating to the air conveyed by means of the air conveying device (14), by means of which parameter the humidity of the conveyed air can be determined, and with an electronic control device (16) which is arranged on the air conveying device (14) and is configured to control the air conveying device (14) in a manner which is dependent on the at least one detected parameter.

Description

VEHICLE SEAT FAN

Description

The invention relates to an air conditioning device for ventilating a vehicle seat according to the preamble of patent claim 1, a vehicle seat according to the preamble of patent claim 13 and a method for operating an air conditioning device for a vehicle seat according to the preamble of patent claim 16.

Air conditioning systems for vehicle seats are already known from the prior art. The publication WO 2019/170622 A1, for example, shows a vehicle seat ventilated by means of a fan, in which sensors are arranged in the seat part and in the backrest of the vehicle seat.

In the known air conditioning systems for vehicle seats, the air flow monitoring units are spatially separated from the air conveying devices and are arranged separately beyond the air conveying devices, for example in the seat cushion of the vehicle seat. However, this circumstance brings with it structural and functional problems. Due to the arrangement of the air flow monitoring units beyond the air conveying devices, on the one hand, a separate fastening of the air flow monitoring units in the seat cushion and, on the other hand, additional cabling of the air flow monitoring units with the air conveying devices and with a control device of the air conditioning device is necessary in order to supply the air flow monitoring units with electrical energy and to enable signal transmission. Additional fastenings and cabling are costly and offer an additional potential for possible errors and failures of the air conditioning device. In addition, the positioning of the air flow monitoring units in the seat cushion is disadvantageous, since the air flow monitoring units in the seat cushion absorb moisture from sweat. of a vehicle seat occupant, which may impair the reliable functioning of the airflow monitoring units and consequently the air conditioning of the vehicle seat. In addition, special measures must be taken when positioning the airflow monitoring units in the seat cushion in order to protect the airflow monitoring units from mechanical damage caused by the occupant and at the same time not to impair the seating comfort for the occupant.

The object underlying the invention is therefore to optimize the reliability and robustness of air conditioning systems for vehicle seats and at the same time to reduce the complexity and costs of air conditioning systems.

The object is achieved with an air conditioning device of the type mentioned above, wherein the at least one air flow monitoring unit is a component of the control device.

Because the at least one air flow monitoring unit is part of the control device, no cable connections are required for signal transmission or for supplying the air flow monitoring unit with electrical energy, so that costs and a high level of cabling effort can be saved and signal paths are shortened. In addition, there is no need for a separate attachment of the air flow monitoring unit beyond the control device, nor for measures to protect the air flow monitoring unit from condensation or mechanical damage, which simplifies the air conditioning device and the vehicle seat, saves further costs and ensures the reliable function of the air conditioning device.

Preferably, the air flow monitoring unit is an integral part of the control device. Preferably, at least one seat surface of the vehicle seat or at least a portion of a seat surface of the vehicle seat is air-conditioned and/or ventilated by means of the air conditioning device. The air conveying device is preferably connected to the control device in a signal-conducting and/or electrically conductive manner. The air conveying device is preferably designed as a blower, preferably as an axial fan or radial fan, particularly preferably as a radial fan, the blower preferably comprising a conveying element with an impeller and impeller blades. The air conditioning device can comprise a plurality of air conveying devices. If the air conditioning device comprises a plurality of air conveying devices, these can, for example, be designed more compactly than a single air conveying device and/or be positioned closer to the seat cushion of the vehicle seat. A plurality of air conveying devices are preferably designed as axial fans. Preferably, a plurality of air conveying devices are networked with one another in a signal-conducting manner, so that, for example, only one of the plurality of air conveying devices has an air flow monitoring unit, the sensor signal being transmitted to all other air conveying devices. Preferably, the blower generates a static pressure increase of the air to be conveyed from 50 Pa to 500 Pa. The control device is preferably set up to control the rotation speed of the air conveying device, in particular the speed of the blower, in order to influence the flow speed of an air flow of the conveyed air through the vehicle seat.

The air flow monitoring unit is preferably designed to monitor the air to be conveyed continuously or at continuous points in time. The air conditioning device can comprise a housing, wherein the control device is arranged together with the air flow monitoring unit and the air conveying device in the housing. A parameter relating to the conveyed air can be, for example, the flow rate, the relative humidity and/or the temperature of the conveyed air. The air conditioning device is designed to air-condition the body areas of an occupant that are in contact with the ventilated vehicle seat or in the vicinity of the seat (local seat air conditioning). The control device is preferably designed to control the air conveying device automatically. The air conditioning device can preferably be manually activated and/or manually controlled by an occupant, for example by means of a switch or by means of a rotary control and/or via an electrical display device of the vehicle. The air conditioning device is preferably automatically activated. Because the air flow monitoring unit is an integral part of the control device, the air flow monitoring unit is arranged in the immediate vicinity of the air conveying device, so that the air flow monitoring unit can directly monitor the air conveyed by the air conveying device. By arranging the air flow monitoring unit directly on the control device, no connecting lines for signal transmission to the control device or supply lines for supplying the air flow monitoring unit with electrical energy are necessary. The air conditioning device is preferably also suitable for ventilating other seating furniture, in particular home and office furniture.

In a preferred embodiment of the air conditioning device according to the invention, the air flow monitoring unit comprises a humidity sensor or the air flow monitoring unit is designed as a humidity sensor which is set up to detect the humidity of the air conveyed by means of the air conveying device. The detected humidity can be a relative humidity or an absolute humidity. The control device is preferably set up to control the air conveying device depending on the detected humidity. The humidity of the conveyed air is influenced by the evaporation of the occupant's sweat and correlates with the occupant's heat stress level. The humidity detected by means of the humidity sensor is closely linked to the occupant's sweat output and consequently to the microclimate between the occupant and the vehicle seat, in particular in the contact areas between the occupant and the vehicle seat. In this way, the control takes place depending on the sweating level and thus the stress level of the occupant. In order to calculate and/or subsequently correct the detected humidity, the air temperature can be detected in addition to the humidity. Preferably, the humidity sensor is designed as a digital humidity sensor. A digital humidity sensor can measure the relative humidity and the air temperature and provide these as digital output signals, whereby an absolute humidity (water content of the air in g per kg). A value for air quality can also be derived from the humidity.

In another preferred embodiment of the air conditioning device according to the invention, the air flow monitoring unit is part of an electronic circuit board of the control device, wherein the air flow monitoring unit is preferably arranged on the electronic circuit board together with a microcontroller for controlling the air conveying device. The microcontroller of the control device is preferably designed to send control signals for controlling the air conveying device, wherein the microcontroller of the control device is connected to the air conveying device in a signal-conducting manner for this purpose. The microcontroller of the control device is preferably designed to receive sensor signals for controlling the air conveying device from the air flow monitoring unit, wherein the microcontroller of the control device is connected to the air flow monitoring unit in a signal-conducting manner for this purpose. In addition, the microcontroller is designed to calculate the control signals on the basis of the sensor data.

The air flow monitoring unit is preferably designed as a surface mount device chip (SMD chip). The air flow monitoring unit is preferably designed to output digital and/or analog control signals. The electronic circuit board is preferably designed to carry the air flow monitoring unit and the microcontroller and to connect them to one another in a signal-conducting manner. The electronic circuit board is preferably designed as a control board. The electronic circuit board is preferably designed as a printed circuit board assembly (PCBA). Thus, electronic communication between the microcontroller, the air flow monitoring unit and the air conveying device enables the air conditioning device to be controlled by means of a single control board. Because both the microcontroller for controlling the air conveying device on the basis of the sensor signals and the air flow monitoring unit are arranged together on a circuit board, it is possible to access both a further higher-level control device which processes the control signals and cable connections between the Air flow monitoring unit and the control device for the air conveying device can be dispensed with. The microcontroller and the air flow monitoring unit are preferably connected to one another via a bus interface, in particular via pulse width modulation (PWM) or via l ² C (Inter-Integrated Circuit). The circuit board is preferably arranged below a motor stator of the air conveying device.

Preferably, the motor stator of the air conveying device is mechanically connected to the circuit board. Preferably, the circuit board is electrically connected to stator windings of the air conveying device, for example by connecting pins or by soldering the stator windings to the circuit board. Preferably, the microcontroller executes control software which is designed to receive and/or process sensor signals from the air flow monitoring unit and/or to calculate control signals. Preferably, the control software is designed to calculate a control algorithm for controlling the air conveying device on the basis of the sensor signals and the control signals.

In a further preferred embodiment of the air conditioning device according to the invention, the control device is designed to switch between at least two different operating states of the air conveying device depending on the parameter detected by the air flow monitoring unit. The control device is preferably designed to switch the operating state of the air conveying device when the parameter relating to the conveyed air falls below or exceeds a defined parameter limit value and/or a defined parameter segregation rate.

In a further development of the air conditioning device according to the invention, the air conveying device comprises a conveying element, wherein the rotational speed of the conveying element of the air conveying device in a first operating state of the at least two operating states differs from the rotational speed of the conveying element in a second operating state of the at least two operating states. The conveying element preferably comprises a paddle wheel and one or more impeller blades. The rotational speed is preferably a target rotational speed. Preferably, the conveying element of the air conveying device is arranged rotatably on the air conveying device. Preferably, the conveying element is mounted on the air conveying device by means of a plain bearing or by means of a ball bearing.

An air conditioning device according to the invention is also preferred in which the rotational speed of the conveying element of the air conveying device is higher in the second operating state than in the first operating state, wherein the control device is set up to set the first operating state when the air parameter determined by means of the air flow monitoring unit is below a defined limit value and/or a defined parameter increase rate, and to set the second operating state when the parameter of the conveyed air determined by means of the air flow monitoring unit is above a defined limit value and/or a defined parameter increase rate. Preferably, the control device is set up to automatically switch between the first and second operating states depending on the at least one parameter. Preferably, the control device is set up to set further operating states in which the rotational speed of the conveying element of the air conveying device differs from the rotational speed in the first and second operating states. The first operating state can serve to convey air to the air flow monitoring unit so that the air flow monitoring unit can determine at least one parameter. Preferably, the air conveying device operates at a low rotation speed so that a generated air flow does not generate any disturbing noises for the occupant. Preferably, the second operating state generates a stronger air flow with a higher air flow speed than the first operating state due to the increased rotation speed. Due to the higher air flow speed in the second operating state, the vehicle seat and thus the occupant are exposed to more air, so that the occupant's sweat evaporates and the occupant is thus cooled. A higher humidity of the conveyed air can indicate that the occupant is sweating. A sweating occupant can indicate that the occupant needs more air conditioning in order to to cool it down and ensure a pleasant microclimate between the occupant and the vehicle seat.

Preferably, the control device is designed to distinguish between sensor signals that are influenced by a sweating passenger and sensor signals that are caused by external influences, such as high humidity in the outside air that enters the interior through an open window and/or an open vehicle door. Two operating states can ensure that the air conditioning device only intelligently increases the rotation speed when necessary and saves energy the rest of the time, thereby increasing the energy efficiency of the air conditioning device.

An air conditioning device according to the invention is also advantageous in which the control device is set up to activate the air conveying device when an occupant approaches the vehicle and/or the vehicle is unlocked and/or the vehicle is started and/or the vehicle seat is contacted by an occupant, wherein the control device is preferably set up to initially set the first operating state of the air conveying device after activation. Preferably, the first operating state is a standard operating state, which can be permanently active when the vehicle seat is occupied by an occupant. The first operating state can be activated automatically when an occupant detection device detects an occupant on the vehicle seat. In addition, the first operating state can be activated automatically when an occupant approaches the vehicle, when the vehicle is unlocked or when the vehicle is started. The first operating state serves to initially convey air to the air flow monitoring unit at a low speed of the air conveying device in order to detect the air humidity.

In a further preferred embodiment of the air conditioning device according to the invention, the air flow monitoring unit comprises a temperature sensor which is designed to detect the temperature of the air conveyed by means of the air conveying device, and/or the air flow monitoring unit comprises a VOC sensor which is designed to detect organically volatile substances in the air conveyed by means of the air conveying device. and/or the air flow monitoring unit comprises a gas sensor which is designed to detect the gas composition of the air conveyed by means of the air conveying device. A VOC sensor is designed to detect volatile organic compounds (VOC for short), for example hydrocarbons, alcohols, aldehydes and/or organic acids.

The gas sensor can in particular be designed to detect the CO2 content and/or the methane content and/or the content of sulfur compounds in the transported air. Alternatively or additionally, the air flow monitoring unit can comprise a sensor for detecting the flow rate of the transported air. Alternatively or additionally, the air flow monitoring unit can comprise a sensor for detecting the density of the transported air. Alternatively or additionally, the air flow monitoring unit can comprise a sensor for detecting the air purity and/or the fine dust content of the transported air. The air quality of the transported air can be derived from all of the detected sensor values. Preferably, the control device is designed to control the air conveying device on the basis of the air quality.

In a further development of the air conditioning device according to the invention, the air conveyed by means of the air conveying device passes through at least one opening which extends between a paddle wheel and impeller blades of the conveying element of the air conveying device and is preferably designed in the form of a gap for detecting the at least one parameter relating to the air conveyed by means of the air conveying device to the air flow monitoring unit.

Alternatively or additionally, the air conveyed by means of the air conveying device passes through at least one opening in the impeller of the air conveying device to the air flow monitoring unit for detecting the at least one parameter relating to the air conveyed by means of the air conveying device.

Alternatively or additionally, the air conveyed by the air conveying device passes through at least one air outlet opening of the air conveying device, from which the conveyed air can be conveyed out of the air conveying device, to the Detecting at least one parameter relating to the air conveyed by means of the air conveying device to the air flow monitoring unit.

In order to record parameters relating to the transported air using the air flow monitoring unit, the transported air must reach the air flow monitoring unit. The air directed to the air flow monitoring unit can simultaneously be used to cool the control device. If the transported air reaches the air flow monitoring unit through at least one air outlet opening of the air conveying device, the air flow monitoring unit is preferably designed such that the air flow monitoring unit is within the range of the air flow through the air outlet opening due to the correct design of its shape and size.

An air conditioning device according to the invention is also advantageous in which the air conveying device comprises a brushless direct current motor. A brushless direct current motor is characterized in particular by its energy efficiency, its freedom from maintenance, and its compact design.

In a further preferred embodiment of the air conditioning device according to the invention, the air conditioning device comprises at least one filter medium, which is designed to be flowed through by the air conveying device and to filter the conveyed air. The filter medium can be an activated carbon filter for odor neutralization. The filter medium can also be a particle filter for filtering particles from the air. The air conditioning device can also comprise a UVC lamp for killing germs in the air.

Furthermore, an air conditioning device according to the invention is advantageous in which the control device and/or the air flow monitoring unit is set up to receive and/or process control signals for controlling the air conveying device from a control device higher up the control device and/or to send sensor signals from the air flow monitoring unit and/or control data relating to the air conveying device to the control device higher up the control device. The higher up control device is preferably designed as a so-called Master control unit and preferably connected to the air conditioning system in a signal-conducting manner via a LIN bus (local interconnect network). The control device is preferably set up to receive manual user inputs from an occupant from a higher-level control unit, for example a manual activation of the air conditioning system and/or a manual setting of an operating state. Manual user inputs can be made, for example, via a touch-sensitive display and/or by means of a button and/or by means of a rotary control.

Preferably, the control device is designed to send sensor signals from the air flow monitoring unit and/or control data relating to the air conveying device to the control device higher-level control unit, which cause the higher-level control unit to activate a seat heater, for example in order to dry the occupant more quickly and/or to protect the occupant from hypothermia due to evaporative cooling caused by the evaporation of sweat. In addition, the higher-level control unit can be prompted by the sent sensor signals and/or control data to control the entire interior air conditioning of the vehicle depending on the sent sensor signals and/or the sent control data. Sensor signals from the air flow monitoring unit and/or control data relating to the air conveying device sent to the higher-level control unit can be, for example, the current operating state of the air conveying device, the air humidity, the air temperature, the air quality, the air gas composition, a seat occupancy state of the vehicle seat and/or possible detected error signals. Control signals received or to be processed by the higher-level control unit for controlling the air conveying device can be, for example, control signals for activating the air conveying device from a sleep mode, information concerning the occupant, for example the approach of an occupant to the vehicle or the seat occupancy by an occupant and/or personal preferences of the occupant with regard to the vehicle air conditioning, in particular HMI inputs (human machine interface). Preferably, the air flow monitoring unit is configured to begin recording sensor data as soon as an occupant approaches the vehicle and/or as soon as an occupant has opened a vehicle door, even before the occupant sits down on the vehicle seat, so that, for example, a high humidity of air entering the vehicle through the vehicle door can be taken into account when recording the sensor data.

The object underlying the invention is further achieved by a vehicle seat of the type mentioned at the outset, wherein the air conditioning device is designed according to one of the above embodiments. With regard to the advantages and modifications of the vehicle seat according to the invention, reference is made to the advantages and modifications of the air conditioning device according to the invention.

In a preferred embodiment of the vehicle seat according to the invention, the air conditioning device is arranged on the underside of a vehicle seat lower part of the vehicle seat or on the back of a vehicle seat backrest of the vehicle seat or is integrated into an air-permeable seat cushion of the vehicle seat lower part or the vehicle seat backrest, wherein the air conveying device is preferably designed to suck the air to be conveyed through the air-permeable seat cushion of the vehicle seat through at least one layer of the seat cushion. The air is preferably sucked through the seat cushion by means of the air conveying device using the air-pull principle. With the air-pull principle, the moist air generated by the sweating occupant is sucked through the seat surface to the air conveying device and thus to the air flow monitoring unit and discharged on the underside or on the back of the seat cushion.

The air-pull principle has several advantages over an air-push principle, where the air is not sucked in from the bottom and/or back, but is blown through the seat from the bottom and/or back. A vehicle seat that has been exposed to sunlight and has warmed up before the occupant sits down and activates the air conditioning system would ensure that the air delivered to the occupant through the seat cushion warms up, thus delivering uncomfortably warm air to the occupant instead of air conditioning the occupant. In a further preferred form of the vehicle seat according to the invention, the vehicle seat comprises an occupant detection device which is designed to detect an occupancy status of the vehicle seat by an occupant, wherein the air conditioning device is preferably designed to be activated and/or controlled depending on the occupancy status of the vehicle seat. The occupant detection device is preferably designed to detect whether the vehicle seat is occupied by an occupant. Preferably, the air conditioning device, in particular an air conveying device of the air conditioning device, is automatically activated as soon as an occupant is detected by means of the occupant detection device. Preferably, the air conditioning device, in particular an air conveying device of the air conditioning device, is kept active as long as the vehicle seat is occupied by an occupant.

The object underlying the invention is further achieved by a method of the type mentioned at the outset, wherein the at least one air flow monitoring unit is a component of the control device.

In a preferred embodiment of the method according to the invention, an air conditioning device according to one of the above embodiments is operated by means of the method. With regard to the advantages and modifications of the method according to the invention, reference is made to the advantages and modifications of the air conditioning device according to the invention.

Preferred embodiments of the invention are explained and described in more detail below with reference to the accompanying drawings, in which:

Fig. 1 an air conditioning device according to the invention in a

Cross-section from the side;

Fig. 2 shows a vehicle seat occupied by an occupant with air conditioning devices according to the invention in a schematic side view; and Fig. 3 shows the temporal course of a rotation speed of an air conveying device as a function of the temporal course of a humidity signal of an air flow monitoring unit.

Fig. 1 shows an air conditioning device 10 according to the invention, which comprises an air conveying device 14 and a control device 16. The air conveying device 14 is designed as a radial fan which sucks in air in the axial direction and blows it out in the radial direction. The air conditioning device 10 is set up to ventilate a vehicle seat 100 by conveying air through at least one seat cushion 102 of a vehicle seat 100 by means of the air conveying device 14. The air conveying device 14 comprises a conveying element 24 which has an impeller 26 and impeller blades 26. The conveying element 24 is rotatably mounted on a motor stator 31 and is set in rotation by means of a DC motor 30 so that the impeller blades arranged on the impeller 26 of the conveying element 24 execute a rotational movement around the motor stator 34. The rotational movement of the impeller blades 28 sets air in motion.

The control device 16 comprises a circuit board 18, which is designed as a PCBA (Printed Circuit Board Assembly). A microcontroller 20 and an air flow monitoring unit 14 are arranged on the circuit board 18 of the control device 16. In addition, further electrical components can be arranged on the circuit board 18, for example coils, capacitors and resistors. The air flow monitoring unit 14 detects the humidity of the air conveyed by the air conveying device 14 during operation of the air conditioning device 10. In addition, the air flow monitoring unit can also detect further parameters relating to the conveyed air, for example the air temperature or the gas composition of the air. The microcontroller 20 can receive sensor signals, which are based on the parameters, in particular on the humidity of the air, from the air flow monitoring unit 12, process them and derive control signals from the sensor signals. The control signals are used to control the air conveying device 14 depending on the parameters detected. If the sensor signals indicate high air humidity or a rapid If the air humidity increases, this may indicate that an occupant 200 sitting on the vehicle seat 100 is sweating more, so that more ventilation of the seat is necessary to cool the occupant more. The microcontroller 20 calculates from the sensor signals of the air flow monitoring unit 12 whether and to what extent the rotational speed R of the conveying element 24 of the air conveying device 14 needs to be adjusted.

The microcontroller 20 and the air flow monitoring unit 12 are connected to one another in a signal-conducting and electrically conductive manner via the circuit board 18. In this way, sensor signals can be sent from the air flow monitoring unit 12 to the microcontroller 20 and the air flow monitoring unit 12 can be supplied with electrical energy. The arrangement of the air flow monitoring unit 12 directly on the circuit board 18 of the control device 16 enables direct communication via a short signal path without additional cable connections between the air flow monitoring unit 12 and the microcontroller 20. In addition, the arrangement of the air flow monitoring unit 12 directly on the air conveying device 14 means that air sucked in by the air conveying device 14 can flow directly to the air flow monitoring unit 12 via openings 32 in the area of the impeller blades 28 of the conveying element 24.

The circuit board 18 of the control device 16 is mechanically attached to the motor stator 34 and is connected in a signal-conducting and/or electrically conductive manner to stator windings of the motor stator 34, so that the direct current motor 30 can be supplied with electrical energy and controlled by means of the control device 16 in order to adapt the rotational speed R of the conveying element 24 of the air conveying device 14 depending on the air parameters detected by the air flow monitoring unit.

Fig. 2 shows a vehicle seat 100 of a vehicle, wherein an occupant 200 sits on the vehicle seat 100. The vehicle seat 100 comprises a vehicle seat lower part 104 and a vehicle seat back 106, wherein the occupant 200 contacts the vehicle seat lower part 104 and the vehicle seat back 106 at least in sections. The vehicle seat 100 comprises two air conditioning devices 10, wherein the vehicle seat lower part 104 and the vehicle seat back 106 are each assigned an air conditioning device 10, which are arranged on the underside of the vehicle seat lower part 104 and on the rear side of the vehicle seat back 106. The air conditioning devices 10 suck air through air-permeable seat cushions 102 of the vehicle seat 100, wherein the air flows along a flow path S from an air-permeable surface layer 108 through a fabric layer 110 into the air conditioning devices 10.

The air sucked in by means of the air conditioning devices 10 absorbs moisture in the vicinity of the occupant 200 and in particular in the vicinity of contact areas of the occupant 200 on the vehicle seat 100, which moisture is created by the evaporation of sweat 202 of the occupant 200 in the area of the surface layer 108 of the vehicle seat 100. Because the air flow monitoring unit 12 is arranged directly on the control device 16 in the air conditioning unit 10, the air conveyed by means of the air conveying device 14 flows at least partially to the air flow monitoring unit 12, so that the moisture of the flowing air can be detected. In addition, the air flow monitoring unit 12 is constantly flowed by air, so that condensation on the air flow monitoring unit 12 and resulting measurement errors are avoided. In addition, the air flow monitoring unit 12 is protected from mechanical stress by the occupant 200 due to the arrangement on the control device 16 directly on the air conditioning device 10 instead of an arrangement within the seat cushion 102, whereby the seating comfort for the occupant 200 is consequently also increased.

The vehicle seat 100 can be equipped with an occupant detection device, so that the air conveying device 14 automatically begins conveying air in a first operating state B1 at a low rotation speed R as soon as an occupant 200 sits down on the vehicle seat 100, so that air reaches the air flow monitoring unit for detecting the humidity. The lower rotation speed R in the first operating state B1 ensures that air constantly reaches the air monitoring unit 12, without burdening the occupant 200 with ventilation noise or avoidable energy consumption. Alternatively or additionally, the air conveying device 14 can start conveying air as soon as the occupant 200 approaches the vehicle from outside or as soon as the vehicle is unlocked.

If the air flow monitoring unit 12 detects that the humidity of the conveyed air exceeds a defined limit value G1 or that the rate of increase in humidity exceeds a limit value, the rotation speed R of the conveying element 24 of the air conveying device 14 is increased by the control device 16 automatically setting a second operating state B2, so that the flow rate of the conveyed air increases and the vehicle seat 100 with the occupant 200 is more ventilated. As a result of greater ventilation of the occupant 200, more sweat evaporates, which is transported away with the air in order to dry and cool the occupant 200 and the vehicle seat 200 and to improve the microclimate between the occupant 200 and the vehicle seat 100.

In this exemplary embodiment, the air conditioning devices 10 are also connected in a signal-conducting manner to a control unit 22 that is higher-level to the control devices 16 of the air conditioning devices 10. The control unit 22 can be set up, for example, to control the air conditioning of the entire vehicle interior. The higher-level control unit 22 can receive and process sensor signals from the control devices 16, in particular from the air flow monitoring unit 12, for example to automatically activate seat heating, and/or send control signals to the control devices 10, for example manual inputs from the occupant on an electronic display device in the vehicle.

Fig. 3 shows a curve of a rotation speed of the air conveyor device 14 as a function of a humidity signal F detected by the air flow monitoring unit 12 over time Z. At a time tO, the air conditioning device 10 is activated. The air conditioning device 10 can be activated, for example, because At time t0, an occupant approaches the vehicle or the vehicle is unlocked. At time tO, the first operating state B1 of the air conditioning device 10 is set by means of the control device 16, in which a low rotation speed R of the air conveying device 14 is set in order to convey air to the air flow monitoring unit 12. In addition, at time tO, the air flow monitoring unit begins to detect the humidity of the conveyed air and outputs an humidity signal F.

At time t1, an occupant 200 sits down on the vehicle seat 100, so that the air conveying device 14 now sucks in air which contains evaporated sweat of the occupant 200, so that the humidity of the air and accordingly the air humidity signal F of the air flow monitoring unit 12 increases.

At time t2, the air humidity and thus the air humidity signal F of the air flow monitoring unit reaches a limit value G1. As soon as the limit value G1 is reached, the control device 16 sets a second operating state B2 of the air conditioning device 10, in which the rotation speed R of the air conveying device 14 is increased. By increasing the rotation speed R of the air conveying device 14, the flow speed of the conveyed air is increased, whereby the ventilation of the vehicle seat 100 and thus the air conditioning of the occupant 200 is intensified in order to cool and dry the occupant 200. In addition, at time t2, a signal can be sent to a higher-level control unit 22 in order to control, for example, a seat heater of the vehicle seat 100 or the interior air conditioning of the vehicle in order to support the drying and air conditioning of the occupant 200 and to prevent hypothermia of the occupant 200.

At time t3, the humidity of the transported air and thus the humidity signal F of the air flow monitoring unit 12 falls below a limit value G2. The humidity of the transported air can fall, for example, if the occupant 200 has been successfully dried and sweats less or if the occupant 200 leaves the vehicle seat 100. If the air flow monitoring unit 12 signals that the limit value G2 is undershot, the control device sets the first operating state B1 with the lower rotation speed R of the air conveyor 14, since air conditioning of the occupant 200 is no longer necessary and the lower rotation speed R in the first operating state B1 reduces the energy consumption and the noise level of the air conveyor 14, with air continuing to be conveyed to the air flow monitoring unit 12 in order to examine the air for a renewed increase in humidity.

Reference symbol

10 Air conditioning system

12 Airflow monitoring unit

14 Air conveyor

16 Control device

18 Circuit board

20 microcontrollers

22 Control unit

24 Conveyor element

26 paddle wheel

28 impeller blades

30 DC motor

32 openings

34 Motor stator

100 vehicle seat

102 seat cushions

104 Vehicle seat base

106 Vehicle seat back

108 Surface layer

110 fabric layer

112 Upholstery foam layer

200 inmates

202 Sweat

B1 , B2 operating status

F Humidity signal

G1 , G2 limit

R rotation speed

S Flow path t0-t3 time points

Z time

Claims

Claims Air conditioning device (10) for ventilating a vehicle seat (100), with at least one air conveying device (14) which is designed to convey air through an air-permeable seat cushion (102) of the vehicle seat (100), at least one electronic air flow monitoring unit (12) which is designed to detect at least one parameter relating to the air conveyed by means of the air conveying device (14), by means of which the humidity of the conveyed air can be determined, and an electronic control device (16) which is arranged on the air conveying device (14) and is designed to control the air conveying device (14) depending on the at least one detected parameter, characterized in that the at least one air flow monitoring unit (12) is a component of the control device (16). Air conditioning device (10) according to claim 1, characterized in that the air flow monitoring unit (12) comprises a humidity sensor or is designed as a humidity sensor which is designed to detect the humidity of the air conveyed by means of the air conveying device (14). Air conditioning device (10) according to one of claims 1 or 2, characterized in that the air flow monitoring unit (12) is part of an electronic circuit board (18) of the control device (16), wherein the

Air flow monitoring unit (12) is preferably arranged on the electronic circuit board (18) together with a microcontroller (20) for controlling the air conveying device (14). Air conditioning device (10) according to one of the preceding claims, characterized in that the control device (16) is set up to switch between at least two different operating states (B1, B2) of the air conveying device (14) depending on the parameter detected by means of the air flow monitoring unit (12). Air conditioning device (10) according to claim 4, characterized in that the air conveying device (14) comprises a conveying element (24), wherein the rotational speed (R) of the conveying element (24) of the air conveying device (14) in a first operating state (B1) of the at least two operating states (B1, B2) differs from the rotational speed (R) of the conveying element (24) in a second operating state (B2) of the at least two operating states (B1, B2). Air conditioning device (10) according to claim 4 or 5, characterized in that the rotational speed (R) of the conveying element (24) of the air conveying device (14) is higher in the second operating state (B2) than in the first operating state (B1), wherein the control device (16) is designed to set the first operating state (B1) when the parameter of the conveyed air determined by means of the air flow monitoring unit (12) is below a defined limit value (G1, G2) and/or a defined parameter increase rate, and to set the second operating state (B1) when the parameter of the conveyed air determined by means of the air flow monitoring unit (12) is above a defined limit value (G1, G2) and/or a defined parameter increase rate. Air conditioning device (10) according to one of claims 4 to 6, characterized in that the control device (16) is designed to activate the air conveying device (14) when an occupant (200) approaches the vehicle, and/or the vehicle is unlocked, and/or the vehicle is started, and/or the vehicle seat (100) is contacted by an occupant (200), wherein the control device (16) is preferably designed to initially set the first operating state (B1) of the air conveying device (14) after activation.

8. Air conditioning device (10) according to one of the preceding claims, characterized in that the air flow monitoring unit (12) comprises one, several or all of the following sensors:

Temperature sensor which is designed to detect the temperature of the air conveyed by means of the air conveying device (14), VOC sensor which is designed to detect organically volatile substances in the air conveyed by means of the air conveying device (14),

Gas sensor which is designed to detect the gas composition of the air conveyed by means of the air conveying device (14).

9. Air conditioning device (10) according to one of the preceding claims, characterized in that the air conveyed by means of the air conveying device (14) passes through at least one opening (32) which extends between a paddle wheel (26) and impeller blades (28) of the conveying element (24) of the air conveying device (14) and is preferably designed in the form of a gap, and/or at least one opening (32) in the paddle wheel (26) of the air conveying device (14), and/or at least one air outlet opening of the air conveying device (14), from which the conveyed air can be conveyed out of the air conveying device (14), to the air flow monitoring unit (12) for detecting the at least one parameter relating to the air conveyed by means of the air conveying device (14). 10. Air conditioning device (10) according to one of the preceding claims, characterized in that the air conveying device (14) comprises a brushless direct current motor (30).

11. Air conditioning device (10) according to one of the preceding claims, characterized in that the air conditioning device (10) comprises at least one filter medium which is designed to be flowed through by the air conveyed by means of the air conveying device (14) and to filter the conveyed air.

12. Air conditioning device (10) according to one of the preceding claims, characterized in that the control device (16) and/or the air flow monitoring unit (12) is designed to

to receive and/or process control signals for controlling the air conveying device (14) from a control device (22) superordinate to the control device (16), and/or

To send sensor signals of the air flow monitoring unit (12) and/or control data relating to the air conveying device (14) to the control unit (22) which is superior to the control device (16).

13. Vehicle seat (100) with an air conditioning device (10), characterized in that the air conditioning device (10) is designed according to one of the preceding claims.

14. Vehicle seat (100) according to claim 13, characterized in that the air conditioning device (10) is arranged on the underside of a vehicle seat lower part (104) of the vehicle seat (100) or on the back of a vehicle seat backrest (106) of the vehicle seat (100) or is integrated into an air-permeable seat cushion (102) of the vehicle seat lower part (104) or the vehicle seat backrest (106), wherein the air conveying device (14) is preferably designed to convey the air through the air-permeable Seat cushion (102) of the vehicle seat (100) to be conveyed through at least one layer of the seat cushion (102). Vehicle seat (100) according to claim 13 or 14, characterized in that the vehicle seat (100) comprises an occupant detection device which is designed to detect an occupancy status of the vehicle seat (100) by an occupant (200), wherein the air conditioning device (10) is preferably designed to be activated and/or controlled depending on the occupancy status of the vehicle seat (100). Method for operating an air conditioning device (10) for a vehicle seat (100), in particular an air conditioning device (10) according to one of claims 1 to 12, with the steps:

Conveying air through an air-permeable seat cushion (102) of the vehicle seat (100) by means of an air conveying device (14),

Detecting at least one parameter relating to the air conveyed by means of the air conveying device (14) by means of an electrical air flow monitoring unit (12), wherein the humidity of the conveyed air can be determined by means of the detected parameter, and controlling the air conveying device (14) depending on the at least one detected parameter by means of an electrical control device (16) which is arranged on the air conveying device (14), characterized in that the at least one air flow monitoring unit (12) is a component of the control device (16).