法国专利FR3075935A1 DOMESTIC AIR PURIFICATION SYSTEM

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专利摘要:
Air purification system comprising: - an air purifier (10) with a control unit (11) and a filtration unit (12), - at least one man-machine interface (31, 32, 33), at least one nomadic air sensor arranged to be able to: be coupled to the air purifier (10), or disconnected from the air purifier (10), the control unit (11) being arranged to control the air purifier (10); filter unit (12) according to at least: • a coupled operating mode taking into account a measurement feedback of the air sensor, and • an uncoupled operating mode not taking into account a sensor measurement feedback. characterized in that in the uncoupled operating mode of the air purifier (10), the man - machine interface (31, 32, 33) is arranged to display measurements of the nomadic air sensor.
公开号:FR3075935A1
申请号:FR1762691
申请日:2017-12-21
公开日:2019-06-28
发明作者:Mathias GANEM；Sebastian Gauthier
申请人:SEB SA；
IPC主号:

专利说明:

DOMESTIC AIR PURIFICATION SYSTEM
The present invention generally relates to an air purifier system intended for use in a house or accommodation of a user, to sanitize, filter or purify the air in the housing.
Document EP2905584B1 discloses a domestic air purification device, but the system described does not allow the user to be informed about the air quality in the entire housing, and the user must move the in each room to process them one by one. This results in a waste of time and unnecessary effort, if a room nevertheless has an acceptable air quality because it will still be treated.
An object of the present invention is to respond to the drawbacks of the prior art document mentioned above and in particular, first of all, to provide an air purifier system which avoids unnecessary efforts and operations the user to process all the rooms in his home.
For this, a first aspect of the invention relates to an air purification system comprising: - an air purifier with a control unit and a filtration unit controlled by the control unit, - at least one man-machine interface, - at least one nomadic air sensor arranged to be able to be: • coupled to the air purifier, or • uncoupled from the air purifier, the control unit being arranged to receive from said at least one man-machine interface an instruction to control the filtration unit according to at least: • a coupled operating mode taking into account a return of measurements from the coupled nomad air sensor, and • a decoupled operating mode not taking disregard a return of measurements from the uncoupled nomadic air sensor, characterized in that in the uncoupled operating mode of the air purifier, said at least one man-machine interface is arranged to display er measurements of the uncoupled nomadic air sensor.
The system according to the above implementation comprises a nomadic air sensor which can be coupled or uncoupled from the air purifier. In other words, the nomadic air sensor can be uncoupled to be moved and detached from the purifier, and it can still function autonomously, to measure the air quality (level of particles such as fine particles, presence of chemical compounds, such as volatile organic compounds, or biological compounds ...), and to communicate with the human-machine interface so that the latter displays the measurement results.
The invention advantageously proposes to provide that the nomadic air sensor can send measurement data to the man machine interface so that these measurements are displayed. Thus the user is informed of the level of air quality.
In addition, if the uncoupled nomadic air sensor is in a space where the air purifier is not located, then the latter operates according to the uncoupled operating mode, without taking into account the measurements of the sensor. nomadic air, because they do not relate to the space where the air purifier is located.
In addition, if the nomadic air sensor can be coupled to the air purifier to transmit the measurements to it to allow the closed-loop and uncoupled operation of the air purifier to allow uncoupled operation, provision may be made attach the detachable air sensor to the air purifier or detach it regardless of the coupled or uncoupled status. In particular, when the nomadic air sensor is in uncoupled status in the remote location (another room in the accommodation), it is obviously detached from the air purifier, but in coupled status, the nomadic air sensor can be attached or detached from the air purifier. Finally, when the nomadic air sensor is attached to the air purifier, it can however be uncoupled to cut off the transmission of the measurements and to force operation in the uncoupled operating mode.
In summary, the user can operate the air purifier in uncoupled operating mode to improve the air quality of a first room in its housing, and at the same time, it can simply remove the sensor nomadic air (detached and uncoupled) in a second room of its housing to make measurements of the air quality in this second room, which will be displayed by the man-machine interface. The measurement is carried out in parallel, and without moving the whole system and in particular the air purifier, which is typically an object of a weight and a bulk which make its handling more difficult than that of the simple air sensor. nomadic.
In particular, according to the above implementation relating to the system, the nomadic air sensor can be put in a coupled state after a coupling action, or be put in a uncoupled state, after an action of uncoupling. The coupled operating mode lasts as long as the nomadic air sensor is in the coupled state, and the uncoupled operating mode lasts as long as the nomadic air sensor is in the uncoupled state.
The man-machine interface can include control buttons, a display screen, or even a touch screen.
Advantageously, the uncoupled operating mode is an open loop operating mode taking no account of the air sensor measurement feedback into account. According to this implementation, the air purifier operates in the simplest possible way, that is to say continuously, without taking account of external feedback.
Advantageously, the air purification system comprises at least one other air sensor, and the uncoupled operating mode comprises: - a closed-loop operating mode taking into account a return of measurements from said at least one other air sensor, or - an open loop operating mode that does not take into account any air sensor measurement feedback. According to this implementation, the system comprises several air sensors, one of which is the nomadic air sensor which can be moved to another room. The other air sensor can then stay in the same place as the air purifier and send it measurement results.
Advantageously, said another sensor is integrated in the air purifier. In particular, the other air sensor can be permanently installed on the air purifier. We can provide minimalist functions for this other air sensor (the other air sensor only measures part of the parameters that the portable air sensor can measure), in order to be able to send the measurements to the air purifier. the most important (for example only a global presence of fine particles, and a single chemical species) and guarantee operation with a basic service. The nomadic air sensor, operating more complete measurements can, when coupled, provide all other measurements to ensure optimal operation.
Alternatively, the other air sensor is a sensor external to the purifier, such as a sensor of a separate air conditioning unit, and which can send data by wire or not to the air purifier.
Alternatively, the other air sensor is a portable, removable sensor, intended to operate with a portable electronic device. Such basic sensors can provide the air purifier with measurements for closed loop operation, while the nomadic air sensor is placed at a distance from the purifier for carrying out autonomous measurements, for its part.
Advantageously, in the coupled operating mode, the control unit takes into account: - only the measurements of the nomadic air sensor, or - measurements of the nomadic air sensor and measurements of said another sensor d 'air. According to the second option of this implementation, the control unit can receive measurements from the two air sensors, and provision can be made to prioritize the taking into account (the most precise sensor measurements are prioritized by example), or a weighting (such as an average), or a complementary consideration (the nomadic air sensor only measures fine particles for example, and the other air sensor only measures certain chemical species ).
Advantageously, the air purification system comprises a nomadic module which integrates the nomadic air sensor and said at least one man-machine interface.
Advantageously, the mobile module includes a digital computing unit. In other words, the nomadic air module is equipped to process the sensor measurements itself, to send adequate data either to the man-machine interface, or to the control unit.
Advantageously, the mobile module includes an autonomous ventilation unit, arranged to create an air flow towards a measurement portion of the mobile air sensor. The sensor can then carry out reliable and representative measurements of the environment in which it is located.
Advantageously, the mobile module comprises means for storing electrical energy. The mobile module is typically a wireless, autonomous module.
Advantageously, the air purification system comprises a portable multimedia electronic device, such as a touch pad or a smart phone, arranged to form a man-machine portable interface and arranged to display measurements of the air sensor. nomadic. Provision may be made for the nomadic module and / or nomadic air sensor to have no display screen, but it can send measurement data to the portable electronic device which is provided with a display screen. It is possible to envisage a link by radio waves, or even by internet or by the telephone network to send the measurement data from the nomadic air sensor to the portable electronic device and / or the man machine interface.
Advantageously, the air purifier comprises a man-machine interface arranged to establish a data connection with the control unit, and to receive a command from a user and send the command to the control unit and / or to the filtration unit. The user can control the air purifier directly from it.
Advantageously, the air purification system comprises: - a first man-machine interface at least arranged to display the measurements of the uncoupled nomadic air sensor during the uncoupled operating mode, - a second man-machine interface arranged to control the air purifier during the uncoupled operating mode.
The system includes two man-machine interfaces, each dedicated to a particular function, during the uncoupled operating mode: this helps the user to control the system.
Advantageously, the first man-machine interface is integral with the nomadic air sensor. In other words, the nomadic air sensor is integrated into the first man-machine interface, which together form an autonomous and portable electronic unit. Advantageously, the second man-machine interface is integral with the air purifier. In other words, the second man-machine interface is installed or integrated on or in the air purifier, which allows the user to control it directly by being next to it (in the immediate vicinity), even if the sensor nomadic air is at a distance (in another room).
We can plan to control the purifier from the first man machine interface, or from the second man machine interface, which gives the user complete freedom.
We can also provide to display the measurements of the nomad air sensor on the first man machine interface, but also on the second man machine interface.
Advantageously, the air purification system comprises complementary contact terminals, arranged to establish electrical contact between the air purifier and the nomadic air sensor when the latter is coupled (or attached) with the purifier air. One can plan to recharge a battery of the nomad air sensor, and / or send measurement data directly by the wired circuit.
Advantageously, the air purification system comprises a contactless connection interface, arranged to establish a contactless connection between the air purifier and the nomadic air sensor.
A second aspect of the invention is a method of using an air purification system according to the first aspect, comprising the steps consisting in: - controlling the air purifier from at least a man-machine interface to operate the filtration unit in a room in a dwelling, - position the uncoupled nomadic air sensor in a location located away from the air purifier, for example in another room of the dwelling , and then control the filtration unit according to the uncoupled operating mode, - display on a man-machine interface measurements of the nomadic air sensor.
This method of use makes it possible to measure an air quality at a location remote from the purifier, which then operates in uncoupled operating mode. It should be noted that the initial operation of the purifier may as well be in coupled or uncoupled operating mode. However, as soon as the nomadic air sensor is in another room (and in an uncoupled state), then the purifier operates in uncoupled operating mode. The user can then check the air quality in one or more rooms without stopping or moving the air purifier.
Advantageously, the method of use comprises the steps consisting in: - moving the air purifier to the place previously located at a distance, - controlling the air purifier from the at least one man-machine interface , - couple the nomadic air sensor with the air purifier, - operate the filtration unit according to the operating mode coupled in said place.
Advantageously, if the nomadic air sensor is coupled and attached to the air purifier and if the purification unit operates in coupled mode of operation, then the method comprises a step consisting in operating the unit automatically. purification in uncoupled operating mode when the nomadic air sensor is detached from the air purifier.
Advantageously, the purification unit is automatically controlled according to the coupled operating mode when the nomadic air sensor is attached again with the air purifier.
Other characteristics and advantages of the present invention will appear more clearly on reading the detailed description which follows of an embodiment of the invention given by way of non-limiting example and illustrated by the appended drawings, in which: FIG. 1 represents a general view of an air purification system with a nomadic module coupled to an air purifier; 2 shows the system of Figure 1, with the nomad module uncoupled from the air purifier; 3 shows a first mode of use of the air purification system of Figures 1 and 2; FIG. 4 represents a second mode of use of the air purification system of FIGS. 1 and 2.
FIG. 1 represents an air purification system which comprises an air purifier 10 which supports a nomadic module 20 coupled and attached to the air purifier 10.
The air purifier 10 typically comprises a control unit 11 and a filtration unit 12 housed in a housing, so as to be able to filter and purify the air of a room in a housing of a user . Provision may be made for the filtration unit 12 to include a motor fan and filters for removing particles and / or chemical compounds from the air.
To this end, a first unit of filters can be provided for removing particles, such as at least one HEPA filter, and a second unit of filters containing an active principle, such as activated carbon, for reacting with chemical compounds or living organisms.
In particular, provision may be made to treat - the particles in suspension in the air, with an aerodynamic diameter (or aeraulic diameter) of less than 10 micrometers denoted PM10, - the finer particles whose diameter is less than 2 , 5 micrometers, called "fine particles" or PM2.5, - volatile organic compounds (formaldehyde, benzene, etc.), - carbon monoxide. To this end, a filtration structure such as that described in document FR3026020A1 can be provided.
The air purifier also includes grids 13 to allow the filtration unit 12 to establish an air flow with the space in which it is located.
The nomad module 20 comprises above all at least one nomad air sensor not shown, and which is arranged to measure, without limitation, at least one or more of the following parameters: - a content of volatile organic compounds ( formaldehyde, benzene, etc.) - a content of carbon monoxide - a content of particles (PM2.5, PM10) - a temperature - a relative humidity - an atmospheric pressure - a content of carbon dioxide [0048] The nomad module 20 may also according to a preferred embodiment comprise a man-machine interface 31, here in the form of a touch screen display, for controlling the control unit 11, and also for displaying measurements (or measurement results) carried out by the nomadic air sensor.
The nomadic module 20 is designed to operate in cooperation with the air purifier 10 (in coupled status), or in autonomy (in uncoupled status). In FIG. 1, the nomadic air module is attached and coupled to the air purifier 10, while in FIG. 2, it is uncoupled and detached from the air purifier 10, and in this latter FIG. 2 a footprint 14 formed in the air purifier 10 to stably accommodate the mobile module 20.
Consequently, a first coupled operating mode can be provided, in which, as in FIG. 1 for example, the air purifier 10 takes into account the measurements of the nomadic air sensor 20 coupled and housed in the nomadic module to control the filtration unit 12. In particular, if the nomadic air sensor detects a content of particles or chemical or biological compounds above a threshold, then the control unit 11 controls the filtration unit 12 to filter and purify the surrounding air. Once the air quality judged satisfactory by the control unit 11 which receives the measurements from the nomadic air sensor, then the control unit 11 can order the stopping of the filtration unit 12.
A second uncoupled operating mode can be provided. In this case, the control unit 11 receives a start-up order according to the uncoupled operating mode from a man-machine interface, and then controls the filtration unit without taking into account the measurements of the nomadic air sensor housed. in the nomad module 20 which is uncoupled. According to the uncoupled operating mode, there is no interaction between the air purifier 10 and the mobile module 20, whether the latter is attached or detached.
Consequently, the mobile module 20 can be turned off or more advantageously placed in a location remote from the air purifier 10, and operate autonomously, without communicating with the air purifier 10. In particular, the user can then place the nomad module 20 in another room of its housing, and display on the man machine interface 31 of the nomad module 20 measurements or measurement results of the nomad air sensor to know if the room in question has a air quality satisfactory or not. This does not require the displacement of the air purifier 10 in this room of the housing, which notably improves the ergonomics of the system. In addition, the uncoupled operating mode makes it possible to operate the air purifier 10 without taking account of the measurements carried out in another room.
We can however very well plan to use another air sensor to provide feedback to the control unit 11, when the mobile module 20 is uncoupled. In this case, the air purifier operates in a closed loop (the ventilation is controlled according to an air quality measurement feedback). We can also plan to operate the air purifier in open loop (without any air quality measurement feedback), if no other air sensor than the nomadic air sensor is provided. In the latter case, the air purifier can only have two states: on or off directly by the user.
We can also provide another man machine interface 33 formed by a portable electronic device (a touch pad or a smart cell phone) to display the measurements of the nomadic air sensor, or to control the control unit. In this case, the man-machine interface 31 of the mobile air module 20 is optional.
We can also consider another man machine interface 32 visible in Figures 1 and 2, and permanently installed on the air purifier 10, to control the latter directly.
Figure 3 shows the use according to the coupled operating mode. The air purifier 10 is located in a room A of the housing of a user, as well as the nomad module 20 which is here in the attached position and in the coupled status. We can also very well plan to use the nomad module 20 in the detached position, but then it must be in room A. In fact, depending on the coupled operating mode, the air purifier 10 is controlled according to measurements of the nomadic air sensor integrated in the nomadic module 20. One can plan to force the operation in coupled mode of operation as soon as the nomadic module 20 is attached to the air purifier 10, to make it pass in coupled state.
Figure 4 shows the use according to the uncoupled operating mode. The air purifier 10 is located in a room A of a user's housing and operates continuously, regardless of the measurements made by the nomadic air sensor which is uncoupled. Indeed, the mobile module 20 which is here in the detached position, is placed in a room B on the lower floor of the housing. In this case, the man-machine interface 31 of the mobile module 20 displays the measurements made by the mobile air sensor.
The transition to uncoupled operating mode can be controlled by the user himself via one of the man machine interfaces, or as soon as the mobile module is physically detached from the air purifier 10. It is also possible to consider automatically switch e to uncoupled operating mode and uncoupled the mobile module 20 as soon as a wireless signal sent to the air purifier 10 by the mobile module 20 has a level below a predetermined threshold, indicating that the mobile module 20 is located beyond a predetermined distance (in short, as soon as the signal is "lost").
We can provide as seen above another man machine interface 33 formed by a mobile phone held by the user standing in a third room C of the housing, and also displaying the measurements of the nomadic air sensor. The flexibility of the system is improved. Thus, the user, only if he sees that the air quality in room B is not satisfactory, can move the air purifier 10 in this room B later.
To allow this use, provision can be made to equip the air purifier 10 and the mobile module 20 with wireless communication units (of the radio wave, WIFI or Bluetooth or other type) to transmit data directly between the devices described, or via an Internet network for example.
Finally, the nomadic air module 20 is equipped with electricity storage means, and also with a fan, in order to be able to operate independently, in particular during the uncoupled operating mode.
It will be understood that various modifications and / or improvements obvious to those skilled in the art can be made to the various embodiments of the invention described in the present description without departing from the scope of the invention defined by the appended claims.

权利要求:
Claims (15)
[1" id="c-fr-0001]
1. Air purification system comprising: - an air purifier (10) with a control unit (11) and a filtration unit (12) controlled by the control unit (11), - at least one human-machine interface (31, 32, 33), - at least one nomadic air sensor arranged to be: • coupled to the air purifier (10), or • uncoupled from the air purifier (10), l the control unit (11) being arranged to receive from said at least one man-machine interface (31, 32, 33) an instruction to control the filtration unit (12) according to at least: • a mode of coupled operation taking into account a feedback of measurements from the coupled nomadic air sensor, and • a decoupled operating mode not taking into account a feedback of measurements from the uncoupled nomadic air sensor, characterized in that in the operating mode uncoupled from the air purifier (10), said at least one man-machine interface (31, 32, 33) is arranged to display measurements of the uncoupled nomadic air sensor.
[2" id="c-fr-0002]
2. Air purification system according to the preceding claim, comprising at least one other air sensor, and in which the uncoupled operating mode comprises: - a closed loop operating mode taking into account a return of measurements from said to minus another air sensor, or - an open-loop operating mode that does not take into account any air sensor measurement feedback.
[3" id="c-fr-0003]
3. Air purification system according to the preceding claim, in which, in the coupled operating mode, the control unit takes into account: - only the measurements of the nomadic air sensor, or - measurements of the sensor d nomadic air and measures another air sensor.
[4" id="c-fr-0004]
4. Air purification system according to one of the preceding claims, comprising a nomadic module (20) which integrates the nomadic air sensor and said at least one man-machine interface (31,32, 33).
[5" id="c-fr-0005]
5. An air purification system according to the preceding claim, in which the mobile module (20) comprises an autonomous ventilation unit, arranged to create an air flow towards a measurement portion of the mobile air sensor.
[6" id="c-fr-0006]
6. Air purification system according to one of the preceding claims, comprising a portable multimedia electronic device, such as a touch pad or a smart phone, arranged to form a man-machine interface (33) portable and arranged to display nomadic air sensor measurements.
[7" id="c-fr-0007]
7. Air purification system according to one of the preceding claims, comprising: - a first man-machine interface (31,33) arranged to display the measurements of the uncoupled nomadic air sensor during the uncoupled operating mode, - a second man - machine interface (32) arranged to control the air purifier (10) during the uncoupled operating mode.
[8" id="c-fr-0008]
8. Air purification system according to the preceding claim, wherein the first man-machine interface (31) is integral with the nomadic air sensor.
[9" id="c-fr-0009]
9. Air purification system according to claim 7 or 8, wherein the second man-machine interface (32) is integral with the air purifier (10).
[10" id="c-fr-0010]
10. Air purification system according to one of the preceding claims, comprising complementary contact terminals, arranged to establish electrical contact between the air purifier (10) and the nomadic air sensor when the latter is coupled with the air purifier (10).
[11" id="c-fr-0011]
11. Air purification system according to one of the preceding claims, comprising a contactless connection interface, arranged to establish a contactless connection between the air purifier (10) and the nomadic air sensor.
[12" id="c-fr-0012]
12. Method for using an air purification system according to one of the preceding claims, comprising the steps consisting in: - controlling the air purifier (10) from the at least one human interface - machine for operating the filtration unit (12) in a room in a dwelling, - positioning the uncoupled nomadic air sensor in a place located away from the air purifier (10), for example in another room of the housing, and then control the filtration unit (12) according to the uncoupled operating mode, - display on a man-machine interface measurements of the nomadic air sensor.
[13" id="c-fr-0013]
13. Method of use according to the preceding claim, comprising the steps consisting in: - moving the air purifier (10) to the place previously located at a distance, - controlling the air purifier (10) from the at least one man-machine interface, - couple the nomadic air sensor with the air purifier (10), - operate the filtration unit (12) according to the operating mode coupled in said place.
[14" id="c-fr-0014]
14. Method of use according to one of claims 12 or 13, wherein, if the nomadic air sensor is coupled and attached to the air purifier (10) and if the purification unit is operating in operating mode coupled, then the method includes a step of automatically operating the purification unit in uncoupled operating mode when the nomadic air sensor is detached from the air purifier (10).
[15" id="c-fr-0015]
15. Method of use according to one of claims 13 or 14, in which the purification unit is automatically controlled according to the coupled operating mode when the nomadic air sensor is re-attached with the air purifier ( 10).

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FR3075935B1|2017-12-21|2019-11-15|Seb S.A.|DOMESTIC AIR PURIFICATION SYSTEM|FR3075935B1|2017-12-21|2019-11-15|Seb S.A.|DOMESTIC AIR PURIFICATION SYSTEM|

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法律状态:
2018-12-31| PLFP| Fee payment|Year of fee payment: 2 |

2019-06-28| PLSC| Publication of the preliminary search report|Effective date: 20190628 |

2019-12-30| PLFP| Fee payment|Year of fee payment: 3 |

2020-12-28| PLFP| Fee payment|Year of fee payment: 4 |

2021-12-30| PLFP| Fee payment|Year of fee payment: 5 |

优先权:

申请号 | 申请日 | 专利标题

FR1762691A|FR3075935B1|2017-12-21|2017-12-21|DOMESTIC AIR PURIFICATION SYSTEM|

FR1762691|2017-12-21|FR1762691A| FR3075935B1|2017-12-21|2017-12-21|DOMESTIC AIR PURIFICATION SYSTEM|

EP18212920.5A| EP3502578A1|2017-12-21|2018-12-17|Domestic system for purifying air|

KR1020180163894A| KR20190075815A|2017-12-21|2018-12-18|Home air purification system|

US16/225,264| US20190193508A1|2017-12-21|2018-12-19|Home air purification system|

BR102018076581-7A| BR102018076581A2|2017-12-21|2018-12-19|DOMESTIC AIR PURIFICATION SYSTEM|

CN201811553979.XA| CN109974156A|2017-12-21|2018-12-19|Domestic air purification system|

CN201822137181.9U| CN210373849U|2017-12-21|2018-12-19|Household air purification system|

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