CN111076320A - Distributed purification system, equipment and method - Google Patents

Abstract

The application discloses distributed purification system, equipment and method, wherein, the system includes: the system comprises at least one monitoring end device and at least one purifying device; different purifying devices in the at least one purifying device are respectively arranged in different spaces, different monitoring end devices in the at least one monitoring end device are respectively arranged in different spaces, and the purifying devices and the monitoring end devices which are in binding relation are arranged at different positions in the same space; the monitoring end equipment is used for detecting the air quality parameters of the space and uploading the air quality parameters of the space; and the purifying equipment is used for determining operation related parameters according to the air quality parameters of the space where the purifying equipment is located, which are uploaded by the monitoring end equipment with the binding relationship with the purifying equipment, and performing air purification treatment on the space where the purifying equipment is located based on the operation mode and the operation related parameters.

Description

Distributed purification system, equipment and method

Technical Field

The present application relates to the field of electronic technologies, and in particular, to a distributed purification system, device, and method.

Background

Due to the improvement of the living standard of modern people, the indoor air purification industry in the current society has a rapid development, and the air purification enterprises which are big and small can reach hundreds of thousands of families.

In the correlation technique, indoor clarification plant has two kinds air purifier and new fan, and the best equipment of solving indoor air pollution is new fan, and new fan classification divide into two kinds, one kind is traditional independent slight positive pressure new trend product, one kind is traditional wall-hanging two-way stream new trend product, and the product of these two kinds of types all can have certain effect to indoor open environment's purification. However, for the whole house purification, the scheme provided in the related art at present cannot effectively ensure the whole house purification effect, and the problem of large noise may occur even if the whole house purification effect is ensured, so that ideal use experience cannot be provided for users.

Disclosure of Invention

The present application provides a distributed purification system, apparatus and method to solve the above-mentioned problems in the prior art.

One aspect of the present application provides a distributed purification system, the system comprising: the system comprises at least one monitoring end device and at least one purifying device; different purifying devices in the at least one purifying device are respectively arranged in different spaces, different monitoring end devices in the at least one monitoring end device are respectively arranged in different spaces, and the purifying devices and the monitoring end devices which are in binding relation are arranged at different positions in the same space; wherein the content of the first and second substances,

the monitoring end equipment is used for detecting the air quality parameters of the space and uploading the air quality parameters of the space;

and the purifying equipment is used for determining operation related parameters according to the air quality parameters of the space where the purifying equipment is located, which are uploaded by the monitoring end equipment with the binding relationship with the purifying equipment, and performing air purification treatment on the space where the purifying equipment is located based on the operation mode and the operation related parameters.

Another aspect of the present application provides a purification apparatus, where the purification apparatus is an apparatus in a distributed purification system, and the purification apparatus has monitoring-end apparatuses that are located at different positions in the same space and have a binding relationship with the purification apparatus; the purification apparatus includes:

the first communication interface is used for acquiring the air quality parameters of the space where the monitoring end equipment with the binding relationship with the first communication interface is located;

and the first processor is used for determining operation related parameters according to the air quality parameters of the space and carrying out air purification treatment on the space based on the operation mode and the operation related parameters.

The monitoring end equipment is equipment in a distributed purification system, and the monitoring end equipment has purification equipment which is located at different positions in the same space and has a binding relationship with the monitoring end equipment; the monitoring end equipment comprises:

the monitoring unit is used for detecting the air quality parameter of the space;

and the second communication interface is used for uploading the air quality parameters of the space.

Another aspect of the present application provides a distributed purification method, which is applied to a distributed purification system, where the distributed purification system includes at least one monitoring device and at least one purification device; different purifying devices in the at least one purifying device are respectively arranged in different spaces, different monitoring end devices in the at least one monitoring end device are respectively arranged in different spaces, and the purifying devices and the monitoring end devices which are in binding relation are arranged at different positions in the same space; the method comprises the following steps:

the at least one monitoring end device detects the air quality parameters of the space where the monitoring end device is located and uploads the air quality parameters of the space where the monitoring end device is located;

the at least one purifying device determines operation related parameters according to the air quality parameters of the space where the purifying device is located and uploaded by the monitoring end device which has a binding relationship with the purifying device;

and the at least one purifying device is used for carrying out air purification treatment on the space based on the operation mode and the operation related parameters respectively.

The application also provides a distributed purification method, which is applied to purification equipment, wherein the purification equipment is equipment in a distributed purification system, the purification equipment is provided with monitoring end equipment with binding relationship, and the purification equipment and the monitoring end equipment with the binding relationship are positioned at different positions in the same space; the method comprises the following steps:

the purification equipment acquires the air quality parameters of the space uploaded by the monitoring end equipment in a binding relationship with the purification equipment;

the purification equipment determines operation related parameters according to the air quality parameters of the space;

and the purifying equipment carries out air purification treatment on the space based on the operation mode and the operation related parameters.

The monitoring end equipment is equipment in a distributed purification system, the monitoring end equipment is provided with purification equipment with binding relationship, and the purification equipment and the monitoring end equipment with the binding relationship are positioned at different positions in the same space; the method comprises the following steps:

the monitoring end equipment detects the air quality parameter of the space where the monitoring end equipment is located;

and the monitoring end equipment uploads the air quality parameters of the space where the monitoring end equipment is located.

Through adopting above-mentioned scheme, just can be based on monitoring end equipment and the clarification plant that set up different positions department in same space among the distributed purification system handles respectively, can carry out air quality monitoring by monitoring end equipment, and then confirm the operation relevant control according to the air quality parameter by clarification plant. So, monitoring end equipment that just can set up different clarification plant and bind in the different spaces in multiple space to all use same clarification plant to carry out air purification in order to bring the great and great problem of noise of amount of wind in avoiding a plurality of spaces, and, owing to separately set up monitoring end equipment and clarification plant, make all have corresponding clarification plant in each space, consequently guaranteed the purifying effect in each space.

Drawings

Fig. 1 is a schematic structural diagram of a distributed purification system according to an embodiment of the present disclosure;

fig. 2 is a schematic structural diagram of a distributed purification system according to an embodiment of the present application;

fig. 3 is a schematic view of a scenario provided in an embodiment of the present application;

fig. 4 is a schematic structural diagram of a distributed purification system according to an embodiment of the present application;

fig. 5 is a schematic diagram of a display interface provided in an embodiment of the present application;

fig. 6 is a schematic structural diagram of a distributed purification system according to an embodiment of the present application;

fig. 7 is a schematic structural diagram of a distributed purification system according to an embodiment of the present application;

FIG. 8 is a schematic structural diagram of a purification apparatus provided in an embodiment of the present application;

fig. 9 is a schematic structural diagram of a monitoring-side device provided in an embodiment of the present application;

fig. 10 is a schematic structural diagram of a cloud server provided in an embodiment of the present application;

fig. 11 is a schematic structural diagram of an application control layer device according to an embodiment of the present disclosure;

fig. 12 is a schematic structural diagram of an operation and maintenance service layer device provided in an embodiment of the present application;

fig. 13 is a first schematic flow chart of a distributed purification method according to an embodiment of the present application;

fig. 14 is a schematic flow chart of a distributed purification method according to an embodiment of the present application;

fig. 15 is a schematic flow chart of a distributed purification method according to an embodiment of the present application;

fig. 16 is a system processing diagram according to an embodiment of the present disclosure.

Detailed Description

In order to make the objects, features and advantages of the present application more obvious and understandable, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is apparent that the described embodiments are only a part of the embodiments of the present application, and not all the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

An embodiment of the present invention provides a distributed purification system, as shown in fig. 1, the system includes: at least one monitoring end device 12, at least one purifying device 11; different purifying devices in the at least one purifying device 11 are respectively arranged in different spaces, different monitoring end devices in the at least one monitoring end device 12 are respectively arranged in different spaces, and the purifying device 11 and the monitoring end device 12 which have a binding relationship are arranged at different positions in the same space; wherein the content of the first and second substances,

the monitoring end equipment 12 is used for detecting the air quality parameters of the space and uploading the air quality parameters of the space;

the purifying device 11 is configured to determine an operation related parameter according to the air quality parameter of the located space uploaded by the monitoring end device having a binding relationship with the purifying device, and perform air purification processing on the located space based on the operation mode and the operation related parameter.

Specifically, the purifying device can be a fresh air fan, and the monitoring end device can comprise an air quality sensor.

The space quality parameters may include one or more parameters that characterize air quality, such as formaldehyde content, PM2.5 index, and the like.

The operation-related parameters may include: whether the purifying equipment is started or not, the air volume after the purifying equipment is started, and the like.

The following describes the scheme provided in this embodiment in detail with reference to a plurality of examples:

examples 1, 1,

In an example provided by this embodiment, the monitoring-side device may directly transmit the air quality parameter to the bound purification device; furthermore, the purifying equipment can directly carry out subsequent treatment according to the air quality parameters of the space where the purifying equipment is located and sent by the monitoring end equipment which has the binding relation with the purifying equipment.

It should be pointed out that can establish point-to-point communication in advance through wireless connection between the clarification plant that monitoring end equipment and it bound, for example, can establish communication link in advance through modes such as bluetooth, WIFI directly link, and then, monitoring end equipment can be periodic carry out air quality monitoring to periodic upload corresponding air quality parameter to clarification plant.

The periodic period length may be set according to an actual situation, for example, the period length may be monitored and uploaded once in 1 second, or may be monitored and uploaded once in 5 seconds, and the period length is not exhaustive in this example.

Examples 2,

In another example provided by this embodiment on the basis of fig. 1, as shown in fig. 2, the distributed purification system further includes: a cloud server 13; wherein the content of the first and second substances,

the cloud server 13 is configured to receive an air quality parameter of a space where each monitoring end device is located, which is reported by each monitoring end device;

correspondingly, the monitoring end device 12 is specifically configured to send the air quality parameter of the space to the cloud server.

And the purifying equipment 11 is used for acquiring the air quality parameters uploaded by the monitoring end equipment which has the binding relationship with the purifying equipment from the cloud server.

That is, examples 1 and 2 provide two ways of uploading air quality parameters and acquiring air quality parameters, respectively, one is to directly transmit the air quality parameters of the monitoring-end device to the purification device through point-to-point communication; and the other method is that the monitoring end equipment uploads the air quality parameters to the cloud server, and then the purifying equipment obtains the air quality parameters uploaded by the monitoring end equipment which has a binding relationship with the purifying equipment from the cloud server.

This example is described in detail with respect to the second manner. By adopting the method, monitoring end equipment and purifying equipment which are positioned at different positions in the same space are bound to obtain the binding relationship between the monitoring end equipment and the purifying equipment; the binding relation between the purifying equipment and the monitoring end equipment can be stored in the cloud server, and can also be stored in the purifying equipment and the monitoring end equipment. Specifically, the binding relationship may be: and the binding relationship between the identifier of the purifying equipment and the identifier of the monitoring end equipment.

In the scheme provided by this example, when the monitoring end device uploads the air quality parameter, the following information may be added to the uploaded information: identification information of the monitoring end equipment; still alternatively, the uploaded information may be augmented with: and the identification information of the monitoring end equipment and the identification information of the bound purification equipment. In addition, a timestamp may be included to detect the air quality parameter.

Correspondingly, the purifying equipment can periodically detect whether new air quality parameters exist from the cloud server, and whether the new air quality parameters are the air quality parameters uploaded by the monitoring end equipment which has the binding relationship with the purifying equipment. For example, the purifying device periodically detects the air quality parameters uploaded by the monitoring end device with the binding relationship from the cloud server, and then checks the timestamp of the purifying device to determine whether the air quality parameters are the latest air quality parameters; if so, the purifying equipment acquires the air quality parameters uploaded by the monitoring end equipment which has the binding relationship with the purifying equipment from the cloud server. Therefore, the purifying equipment can acquire the current air quality parameters of the space.

It should be noted that the number of monitoring-side devices may be 1 or may be plural.

In one embodiment of this example, referring to fig. 3, a decontamination apparatus and a monitoring end apparatus may be provided in each room, such as rooms 1 and 2 in the figure, respectively, decontamination apparatus-1 and decontamination apparatus-2, and monitoring end apparatus-1 and monitoring end apparatus-2. Taking the room 1 as an example, the monitoring end device-1 (such as an air quality sensor) uploads periodically detected air quality parameters to the cloud server; the purification equipment-1 in the room can acquire the air quality parameters of the room from the cloud server, and further control the operation mode and the operation parameters of the purification equipment.

In another specific implementation of this example, each room may be provided with a purifying device, only one monitoring-end device may be provided, for example, there are 2 rooms in the house, and each room is provided with a purifying device-1 and a purifying device-2, respectively, and in addition, one monitoring-end device may be provided in one room. Monitoring end equipment such as an air quality sensor) uploads periodic detected air quality parameters to a cloud server; the purification equipment-1 and 2 in the room can acquire the air quality parameters uploaded by the monitoring end equipment from the cloud server, and further control the operation mode and the operation parameters of the purification equipment.

In another specific implementation of this example, each room may be provided with a purifying device, and a plurality of purifying devices may correspond to one monitoring-end device, or one purifying device may correspond to one monitoring-end device, for example, there are 3 rooms, rooms 1, 2, and 3 in a house; the room 1 is provided with a purifying device-1 and a monitoring end device-1; the rooms 2 and 3 are only provided with one monitoring end device-2. The monitoring end equipment 1 and 2 can upload the periodically detected air quality parameters to the cloud server; the purification devices-1, 2, 3 in the room can acquire corresponding air quality parameters from the cloud server, and then control the operation modes and operation parameters of the purification devices.

Further, the purifying device 11 is further configured to continue to periodically obtain a new air quality parameter of the located space detected by the corresponding monitoring-end device after performing air purification processing on the located space based on the determined operation mode and the operation related parameter, adjust the operation related parameter based on the new air quality parameter of the located space, and perform air purification processing on the located space based on the adjusted operation related parameter.

It can be understood that after the purification equipment is started, the operation mode and the operation parameters of each purification equipment are determined for the first time; each purifying device can continuously acquire the air quality parameters of the space where the purifying device is located, which are uploaded by the corresponding monitoring end device, from the cloud server; further, the operation-related parameters are adjusted with the air quality parameters.

Still further, the purification device is further configured to adjust an operation-related parameter to be a lowest purification gear or a standby state when it is determined that the air quality in the space where the purification device is located reaches a preset quality based on the air quality parameter.

That is, along with the air quality parameters monitored in real time, when it is determined whether the air quality in the current space is excellent (i.e., the preset quality), the purification process may be stopped.

Here, the predetermined mass may be a formaldehyde content of 0, a PM2.5 less than a predetermined value, etc., and is not limited herein. The preset quality can be set by a user according to actual requirements, or can also be a preset default value.

Examples 3,

With reference to the foregoing example 1 or example 2, this example adds an application control layer in the distributed purification system; referring to fig. 4, including:

the application control layer device 14 is used for acquiring and displaying the operation state of the at least one purifying device and the air quality condition of the at least one space; the cloud server is used for acquiring instruction information; wherein, the instruction information comprises a system purification mode;

correspondingly, the cloud server 13 is further configured to determine at least one purifying device performing purifying processing and at least one monitoring-end device corresponding to the purifying device according to the system purifying mode in the instruction information uploaded by the application control layer device.

In this example, the application control layer device may be specifically a terminal device on the user side, for example, an intelligent device on the user side, and an intelligent device similar to a mobile phone, a tablet computer, and the like.

By applying the control layer device, a user can control whether to start the system, specifically whether to start at least one purifying device; correspondingly, when a user controls to start a certain purifying device through the application control layer device, the monitoring end device with the binding relationship with the purifying device can be started at the same time.

In addition, the user can set requirement information through application control layer equipment (such as an intelligent terminal), and the requirement information is sent to the cloud server;

correspondingly, the cloud server also determines the number of the purifying devices required by the user and the number of the corresponding monitoring end devices according to the demand information.

Specifically, the requirement information may include at least one of: the number of spaces in which the user is located, the size of each space, and the number of event population per space. Wherein each space may be a room in a house where the user is located, such as a living room, a bedroom, a kitchen, a bathroom, etc. The cloud server can determine the configuration of the purification equipment required by different spaces according to the demand information, for example, the purification equipment in a positive pressure type can be arranged in one room, and the purification equipment in negative pressure type can be arranged in the other rooms; in addition, parameters such as the maximum power of the purifying equipment set in different rooms may also be different, for example, the square meter of a room is larger, the maximum power of the purifying equipment may be larger, and otherwise, the maximum power may be smaller; for another example, if there are many people that may come in and go out of some rooms, then the purification device with the larger maximum power can be used, and in places such as the toilet, 1 person usually comes in and goes out and the square meter is also smaller, and the purification device with the smaller maximum power can be configured. Of course, the processing of the selection device may be executed according to a preset algorithm configured in the cloud server (or in the terminal device of the user), and a specific algorithm is not limited in this embodiment.

After the purifying devices and the monitoring-side devices of different rooms in the house where the user is located are determined based on the processing, the user can also control the opening and closing of the purifying devices (and the corresponding monitoring-side devices) by applying the control layer device. The starting or closing instruction can be sent to the cloud server for the application control layer; and the cloud server controls the on or off of at least one purifying device and at least one monitoring end device according to the on or off instruction.

Or, the user may also control the control mode of the distributed system through the application control layer device, for example, the user may determine the currently adopted mode through a mode selection interface displayed by the application control layer device; and then, the mode selection of the user is sent to the purifying equipment and the corresponding monitoring end equipment through the cloud server, so that each purifying equipment is controlled.

Specifically, the control modes in the distributed purification system can be divided into four control modes of manual control, intelligent linkage and distributed linkage control:

manual control: the user can independently control equipment in the distributed purification system through a mobile phone or a press key of the machine body, and can control the functions of starting and shutting down, running mode, air volume, whether to start electric auxiliary heating and the like of any new fan (namely purification equipment); these controls can be uploaded to the cloud server through application control layer equipment, and then are realized by the transmission of control information to clarification plant by the cloud server.

Intelligent control: the method comprises the steps that a user only needs to start up equipment in a fresh air system, all equipment is in an intelligent mode after the equipment is started up, the user does not need to do any other operation, and the equipment automatically judges an operation mode, operation gear air quantity, whether an electric auxiliary heating function needs to be started or is in a standby state or not through sensor data of the equipment acquired by a cloud server;

intelligent linkage control: linkage between the purification devices can be realized, for example, when a user starts an intelligent purification mode of the main device and selects an auxiliary fresh air device linked with the main device to complete establishment of a linkage control system, the auxiliary fresh air device (which can be an auxiliary purification device) serves as an air monitoring end device of the whole intelligent linkage control system, and the operation mode and air volume adjustment of the whole intelligent linkage control system take sensor data of the auxiliary fresh air device as a priority judgment condition to achieve the purpose of whole-house purification;

distributed linkage control: the intelligent monitoring system is characterized in that an independent sensing layer Sensor is independently added on the basis of intelligent control, namely monitoring end equipment is placed at a proper position according to the difference of the area and the pattern of a house, the uploaded detection data detected by the independent monitoring end equipment controls the operation mode and the air volume of at least one purifying device in the distributed purifying system, and when the air quality of the independent sensing layer reaches the optimal state, all rooms are proved to have the optimal air quality, so that the optimal effect of purifying the whole house can be ensured.

Furthermore, each purifying device can synchronize the current running state to the cloud server; the application control layer can periodically acquire the running state of each purifying device and the control quality condition uploaded by the monitoring end device from the cloud server;

furthermore, the control layer device can be displayed for the user at the terminal device of the user according to the acquired information, for example, referring to fig. 5, the user can visually see that the operation state of the purifying device in the toilet is the standby state, and the air quality is excellent; the operation state of the purification equipment in the living room is a purification state, the air quality is general, and the like, or the current PM2.5 and the formaldehyde content can be displayed. Taking fig. 5 as an example, in the bedroom 2, the operation state of the purification device is that the opening air volume is low, in the air quality, PM2.5 is a2, and the formaldehyde content is b 2; or the operating state of the purification equipment in the toilet is closed, and the air quality is excellent. Of course, the specific display content may be different from that of fig. 5, but any display manner is within the protection scope of the present example.

In addition, when the distributed purification system is in an open state, the user can also send user instruction information through the application control layer device, for example, the user instruction information may include a purification target, a purification mode, and the like. Correspondingly, the cloud server can adjust the current purification equipment to be started and the corresponding monitoring end equipment according to the user instruction information, and determine the operation state, the operation parameters and the like of each purification equipment after being started; and then the cloud server initiates a control instruction to the purifying equipment so as to control the purifying equipment to carry out purifying treatment according to the control instruction.

Examples 4,

Based on the foregoing example, as shown in fig. 6, an operation and maintenance service layer device 15 is further added in this example, and is used for performing fault detection and life detection on at least one purification device through the stored data of the cloud server; and pushing reminding information to the application control layer equipment.

That is, the cloud server 13 may further include a cloud data storage, which may store the operation data of the purifying device for a period of time; the operation and maintenance service layer 15 may then periodically obtain these data from the cloud server 13 for analysis to determine whether any of the decontamination apparatuses is malfunctioning, and to determine the remaining life of each decontamination apparatus. If it is determined that one purifying device has a fault or has a short service life, a prompt can be initiated for the user through the application service layer, so that the user can maintain or replace the corresponding purifying device in time.

For the foregoing examples, this embodiment provides a specific implementation block diagram, for example, see fig. 7, where the specific implementation block diagram includes an application control layer (application control layer device), a network transport layer, a cloud server, a Sensor layer (composed of monitoring end devices), a purification device layer (composed of purification devices), and an operation and maintenance service layer (operation and maintenance service layer device);

and the data exchange among all the levels is realized through the cloud server layer, so that the coordination control of the whole distributed purification system is completed. For example, the user can set which areas are purified and which areas are not purified, and set the indoor air index to be reached at the application end, so that all the devices enter the automatic control state, and automatically purify according to the air index set by the user, the system forms a purification map in the cloud database according to the use habit of the user, and the system is started to default and can purify according to the purification map, so that the fresh air volume balance of the whole system is realized.

The application control layer (application control layer equipment) mainly realizes interaction between a user and the equipment, and the user can intuitively preview the equipment state and the current indoor air quality condition through a visual interface of the mobile phone APP; the linkage control is that a user can simply select a machine to be linked or intelligent monitoring cloud equipment to complete linkage building between all indoor fresh air equipment and intelligent monitoring cloud equipment through an intelligent purification mode of an APP (application), the user only needs to build once, and in use, all the equipment can completely and autonomously control the operation modes of all hosts in the distributed purification system through the detection result of the intelligent cloud monitoring end equipment, so that full intelligent operation is achieved;

the network transmission layer is mainly a network protocol for realizing interconnection between the mobile phone and the cloud, between the cloud and the equipment, between the equipment and the equipment, and between the equipment and the user, an MQTT protocol is used between the APP and the purifying equipment, and a WiFi or 5G network is used for connecting the equipment and the cloud through a network;

the Cloud server Cloud is mainly used for data storage and data exchange among all other levels, so that normal interaction of the distributed intelligent oxygen fresh air system is realized;

the sensing layer Sensor (comprising one or more monitoring end devices) is a judgment basis for the autonomous operation of the whole distributed intelligent oxygen fresh air system, the devices judge by acquiring data uploaded by the sensing layer Sensor to the cloud, and control the running air quantity gear through judgment to finish the core dominant air quantity balance in the distributed intelligent oxygen fresh air system;

the purifying equipment layer is core equipment in the distributed intelligent oxygen fresh air system, wherein the core equipment comprises positive pressure equipment and negative pressure equipment with different air volumes, the positive pressure equipment and the negative pressure equipment are reasonably matched through a core calculation method according to different use environments, and finally, the reasonable distributed distribution of all the purifying equipment is completed;

the operation and maintenance service layer mainly performs background management and background analysis, performs fault monitoring and service life monitoring through data stored in the cloud server, reminds users of using conditions in an active pushing mode, and performs early warning in time to achieve the best purification effect.

Based on the description of aforementioned a plurality of examples, can see that, the main problem that the scheme solution that this embodiment provided is monitoring end equipment data validity, traditional new trend wind pressure are not enough or air short circuit indoor air replacement rate is low, the indoor distal end purification efficiency of traditional new trend is not good can not accomplish best effect, the fastest efficiency scheduling problem that the whole house purifies, and the concrete analysis is as follows:

and (3) data validity of the monitoring end equipment: the traditional monitoring uses a sensor built in the equipment, and the operation mode of the indoor environment monitoring and adjusting equipment is carried out according to the data reported by the built-in sensor, but the monitoring mode has a fatal defect that the air around the fresh air equipment can be rapidly cleaned because the fresh air equipment continuously introduces clean air, the operation wind speed can be reduced when the built-in sensor detects that the air is clean, but the actual space far away from the fresh air equipment indoors is not effectively purified, so that the data of the equipment at the monitoring end is not the data after the whole room is purified;

distributed purification system separates monitoring end equipment alone, according to the overall arrangement in house and the difference of area, places monitoring end equipment at distributed intelligence oxygen new trend system's central point and puts, and this independent monitoring end equipment's advantage is only when clean air spreads the whole room after, and monitoring end equipment just can monitor the air quality excellent, and the data of the independent monitoring end equipment that new trend equipment gathered just can adjust the operational mode and the amount of wind this moment, just so can guarantee that indoor whole space keeps clean constantly.

Traditional new trend (that is traditional clarification plant) wind pressure is not enough or the air short circuit indoor air replacement rate is low: the defects of traditional one-way flow fresh air and two-way flow fresh air are mainly overcome, the traditional one-way flow fresh air is mainly characterized in that fresh air is continuously conveyed indoors by micro-positive pressure, indoor dirty air is extruded outdoors through a window seam and a door seam, whole-house purification can be realized if long-time large-air-volume operation is carried out, but the problems are that the air around the equipment can be quickly cleaned, the air volume can be reduced after the air around the equipment is clean, the air pressure is reduced, and therefore the dirty air at the far end of the indoor cannot be well replaced, and the whole-house purification effect is influenced; the principle of traditional hanging bidirectional flow new trend is good, there is the air inlet to have and airs exhaust, can form the balance of wind pressure, the temperature exchange of new trend can be played to full heat exchange filter core in addition, but the shortcoming is also more obvious, because the air outlet and the return air inlet of traditional hanging bidirectional flow new trend are all on the local, two wind gap distances are nearer, the fresh air clean air of input can be outdoor by the direct suction of return air inlet, the air around the new trend equipment can form a circulation, the clean air of new trend equipment input can't reach farther place, cause the unable replacement that obtains of distal end air, influence whole room purifying effect equally.

The distributed purification system carries out personalized customization on the purification requirements of users in an equipment stationing intelligent centralized control mode, the users only need to input simple parameters such as the area of a house, the number of bedrooms and the number of users on a front section page, a background calculates and extracts the parameters according to the parameters input by the users through cloud data, different customization schemes are provided, the equipment only needs to purify a very small space according to the distribution of indoor areas, a detection end is arranged at the far end of fresh air equipment, and the equipment can adjust the operation mode and the air volume only after the fresh air is filled in a whole house, so that the indoor air is quickly cleaned and can be kept clean for a long time, and the best effect and the fastest efficiency of the whole house purification are realized;

it can be seen that the scheme that this embodiment provided has changed original new trend purification mode, and traditional new trend purification mode is because the drawback of wind pressure and short circuit can't effectual carry out whole room and purify, and this embodiment then can be fast, efficient accomplishes whole room and purifies.

In the distributed purification system, all terminal devices are controlled by taking the independent monitoring end device as a data basis, including all purification devices, the terminal devices used by the user (i.e. application control layer devices), operation and maintenance service layer devices, and the like. This design is mainly the validity of solving the detection end data, the detection end in traditional clarification plant is all inside the fuselage, it is all the air around the clarification plant to see out traditional detection data as aforementioned analysis, however the air purification in this space can be comparatively fast, so under the condition that the far-end air does not obtain purifying, clarification plant just adjusts to little amount of wind operation, the purpose that whole house purified can't be accomplished equally, separate out monitoring end equipment in the three father's distributed new trend, put the position far away from equipment, can guarantee the validity of data monitoring, finally reach the purpose that lasts whole house purification.

In addition, the foregoing solution also provides an apparatus configuration calculation method: the calculation method includes the steps that data are extracted from a background server (for example, an application background server connected with a user through an APP can be used for the user, certainly, the cloud server can also be used for the user), an optimal fresh air solution is recommended to the user according to scientific calculation, the user only needs to simply input data such as the house area, the number of users and the number of bedrooms on a page applied by the APP, the corresponding scheme (for example, the number of configured purification devices) can be calculated in the background, and the method is not suitable for the traditional purchasing scheme, and the user cannot make the maximum air volume using noise of the fresh air machine.

When a user binds all devices of the distributed purification system by using the APP, the fresh air purification device and the independent monitoring end device can complete linkage binding relationship, namely the independent monitoring end device uploads data through a network cloud, the fresh air purification device can read the data uploaded by the independent monitoring end device in real time, and the mode and the air volume of the fresh air purification device which needs to be adjusted and operated are judged according to the uploaded data; and when the read air quality is excellent, all the devices in the distributed purification system enter a lowest gear or a standby state, all the purification devices still continuously monitor cloud data in real time at the moment, and can be started again and increase the air volume after the indoor air pollution condition rises to some extent, and if the purification devices are provided with monitoring sensors, the data of the independent monitoring end devices are used as priority judgment conditions.

In addition, the distributed fresh air can be provided by the embodiment, the required fresh air volume and the model configuration are calculated scientifically according to different house layout areas and different living habits, the distribution and the distribution of the fresh air equipment are carried out, and all the fresh air purification equipment can be controlled by one intelligent monitoring cloud system, so that the balance of the indoor fresh air volume is realized. And the whole-house purification is realized, no dead angle is left for indoor purification, and the whole indoor space can be paved with the purified clean air quantity most effectively at the fastest speed through distributed distribution. For far-end air, namely, an independent space far away from the fresh air equipment, for example, the fresh air equipment is arranged in a living room, the bedroom belongs to the far-end air, and the distributed fresh air aims to solve the problem that the far-end air cannot be effectively purified because the purified clean air cannot be blown to the far room by the traditional fresh air.

Independent monitoring end equipment is different from the monitoring sensor of traditional new trend itself, and traditional sensor is installed on the fuselage, causes the purification illusion easily, because the air quality around the equipment purifies comparatively fast, will adjust the operation amount of wind when the sensor detects the excellent, and the remote air does not effectively purify in fact, and that independent monitoring end equipment is the rational position of putting monitoring sensor in distributed system, and the data that detect out like this are just effective.

The advantage and disadvantage contrast of the distributed purification system that traditional new trend of concrete analysis and this embodiment provided:

the technical defects of the traditional independent micro-positive pressure fresh air product are that the micro-positive pressure air pressure is not enough, when one micro-positive pressure fresh air is installed in a living room, the air pressure of the micro-positive pressure fresh air is not large enough, a bedroom door cannot be broken through and enters a bedroom, even if the maximum air volume is opened, the effect of purifying the far end of a house cannot be too large, meanwhile, the maximum air volume is opened, the noise is very large, and the normal rest and sleep of indoor personnel are affected, so the independent micro-positive pressure fresh air has the defects of low air exchange efficiency and poor purifying effect of the far end of the house;

the technical defects of the traditional wall-mounted bidirectional flow fresh air product are that air short circuit is easily caused, micro-positive pressure cannot be formed, outdoor air is purified and input into a room through a fresh air blower, however, an air return opening is arranged below or on the left and right sides of the machine, the flow direction of clean air which is just input into the room is always the direction with the minimum flow direction pressure, and the air return opening just forms negative pressure, so that the effect of air short circuit can be formed and only a small space can be purified, the principle is somewhat like an air purifier, and the whole room purification or the indoor far-end purification effect cannot be realized;

the distributed purification system is designed for solving the defects, namely distributed fresh air refers to the distribution and the distribution of fresh air equipment according to different building pattern areas and different types of machine type configurations and the required fresh air quantity is scientifically calculated according to different living habits, and all the fresh air machines can be controlled by an intelligent monitoring cloud system to realize the balance of indoor fresh air quantity. The popular points are that the required fresh air volume and the model configuration are calculated according to the difference of indoor areas, the difference of the number of rooms and the difference of the number of users, the distribution and the distribution of the fresh air fans are performed, for example, the fresh air fans with the air volume required by the large area of a living room and the fresh air fans with the air volume required by the large area of a bedroom are distributed according to the area of each area, the fresh air fans with the proper air volume are not distributed according to the total area of the whole house, and the fresh air fans can be controlled by an intelligent monitoring end device, so that the balance of the indoor fresh air volume is realized, and the scientific and reasonable whole-house purification is realized.

The embodiment of the invention provides a purifying device, which is a device in a distributed purifying system, and the purifying device is provided with a monitoring end device which is located at different positions in the same space and has a binding relationship with the purifying device; as shown in fig. 8, the purification apparatus includes:

the first communication interface 81 is used for acquiring the air quality parameters of the space where the monitoring end equipment with the binding relationship with the first communication interface is located;

and the first processor 82 is used for determining operation related parameters according to the air quality parameters of the space, and performing air purification treatment on the space based on the operation mode and the operation related parameters.

Correspondingly, the embodiment also provides monitoring end equipment, wherein the monitoring end equipment is equipment in the distributed purification system, and the monitoring end equipment has purification equipment which is located at different positions in the same space and has a binding relationship with the monitoring end equipment; as shown in fig. 9, the monitoring-side device includes:

a monitoring unit 91 for detecting air quality parameters of the space;

and the second communication interface 92 is used for uploading the air quality parameters of the space.

Correspondingly, this embodiment further provides a cloud server, as shown in fig. 10, the cloud server includes:

a third communication interface 1001, configured to receive the space quality parameter of the space where the monitoring-end device is located, which is uploaded by the monitoring-end device; and providing space quality parameters of the space where the purifying equipment is located for the purifying equipment.

Specifically, the purifying device can be a fresh air fan, and the monitoring end device can comprise an air quality sensor.

The space quality parameters may include one or more parameters that characterize air quality, such as formaldehyde content, PM2.5 index, and the like.

The operation-related parameters may include: whether the purifying equipment is started or not, the air volume after the purifying equipment is started, and the like.

The monitoring end equipment can directly transmit the air quality parameters to the bound purification equipment through the second communication interface 92; furthermore, the first communication interface 81 of the purifying device can directly perform the subsequent processing according to the air quality parameter of the space where the monitoring end device with the binding relationship is located.

In addition, the third communication port 1001 of the cloud server receives the air quality parameter of the space where the monitoring end device is located, which is reported by each monitoring end device in at least one monitoring end device;

correspondingly, the second communication interface 92 of the monitoring-side device sends the air quality parameter of the space to the cloud server.

The first communication interface 81 of the purifying device obtains the air quality parameters uploaded by the monitoring end device having the binding relationship with the cloud server.

In the solution provided in this example, the monitoring-side device may further include a second processor, and when the monitoring-side device uploads the air quality parameter through the second communication interface 92, the second processor of the monitoring-side device may add, in the information: identification information of the monitoring end equipment; still alternatively, the uploaded information may be augmented with: and the identification information of the monitoring end equipment and the identification information of the bound purification equipment. In addition, a timestamp may be included to detect the air quality parameter.

Further, after the first processor 82 of the purifying device performs air purification processing on the located space based on the determined operation mode and the operation related parameters, it continues to periodically acquire new air quality parameters of the located space detected by the corresponding monitoring end device through the first communication interface 81, adjusts the operation related parameters based on the new air quality parameters of the located space, and performs air purification processing on the located space based on the adjusted operation related parameters.

Still further, the first processor 82 of the purifying apparatus adjusts the operation-related parameter to be the lowest purifying gear or the standby state when it is determined that the air quality in the space where the purifying apparatus is located reaches the preset quality based on the air quality parameter.

As shown in fig. 11, the application control layer device may include a fourth communication interface 1101 for acquiring the operation status of the at least one purification device and the air quality condition of the at least one space; the cloud server is used for acquiring instruction information;

a display unit 1102 for displaying the operation state of the at least one purification apparatus and the air quality condition of the at least one space; wherein, the instruction information comprises a system purification mode.

Correspondingly, the cloud server further comprises a third processor, and the third processor is used for determining at least one purifying device for performing purifying treatment and at least one monitoring end device corresponding to the purifying device according to the system purifying mode in the instruction information uploaded by the application control layer device.

In addition, the application control layer device acquires the requirement information set by the user through the fourth communication interface 1101, and sends the requirement information to the cloud server;

correspondingly, the third processor of the cloud server also determines the number of the purifying devices required by the user and the number of the corresponding monitoring end devices according to the demand information.

As shown in fig. 12, in this example, an operation and maintenance service layer device is further added, including:

a fifth communication interface 1201, configured to acquire data stored in the cloud server; pushing reminding information to the application control layer equipment;

the fifth processor 1202 is configured to perform fault detection and life detection on at least one purification device according to the data of the cloud server; and generating the reminding information.

That is to say, the cloud server can also contain a cloud data storage, can keep the operating data of clarification plant in a period of time.

The functions executed by the functional modules in the devices in this embodiment are the same as those in the system embodiment described above, and therefore, the detailed description thereof is omitted here.

In another embodiment, a distributed purification method is further provided, which is applied to a distributed purification system, wherein the distributed purification system comprises at least one monitoring end device and at least one purification device; different purifying devices in the at least one purifying device are respectively arranged in different spaces, different monitoring end devices in the at least one monitoring end device are respectively arranged in different spaces, and the purifying devices and the monitoring end devices which are in binding relation are arranged at different positions in the same space; as shown in fig. 13, the method includes:

s1301: the at least one monitoring end device detects the air quality parameters of the space where the monitoring end device is located and uploads the air quality parameters of the space where the monitoring end device is located;

s1302: the at least one purifying device determines operation related parameters according to the air quality parameters of the space where the purifying device is located and uploaded by the monitoring end device which has a binding relationship with the purifying device;

s1303: and the at least one purifying device is used for carrying out air purification treatment on the space based on the operation mode and the operation related parameters respectively.

Further, aiming at the purifying equipment, the purifying equipment is equipment in a distributed purifying system, the purifying equipment is provided with monitoring end equipment with binding relationship, and the purifying equipment and the monitoring end equipment with binding relationship are positioned at different positions in the same space; in the distributed purification method provided in this embodiment, as shown in fig. 14, the method includes:

s1401: the purification equipment acquires the air quality parameters of the space uploaded by the monitoring end equipment in a binding relationship with the purification equipment;

s1402: the purification equipment determines operation related parameters according to the air quality parameters of the space;

s1403: and the purifying equipment carries out air purification treatment on the space based on the operation mode and the operation related parameters.

Aiming at monitoring end equipment, the monitoring end equipment is equipment in a distributed purification system, the monitoring end equipment is provided with purification equipment with binding relationship, and the purification equipment and the monitoring end equipment with the binding relationship are positioned at different positions in the same space; in the distributed purification method provided by this embodiment, as shown in fig. 15, the method includes:

s1501: the monitoring end equipment detects the air quality parameter of the space where the monitoring end equipment is located;

s1502: and the monitoring end equipment uploads the air quality parameters of the space where the monitoring end equipment is located.

The specific functions and processes of each device in the distributed purification method in this embodiment are the same as those in the system embodiment, and are not described again here.

Finally, the specific processing of the distributed purification system will be described with reference to fig. 16:

wherein, the user can check and control the state of the distributed purification system through the APP, namely, the application control layer device; and can send the control command to the cloud server through APP; the cloud server can control the shutdown (or startup) of the distributed purification system according to the control instruction; correspondingly, the distributed purification system is started or shut down, and specifically, the positive pressure purification equipment 1, 2 and 3 and the negative pressure purification equipment in the system are controlled to be started or shut down;

at the moment, the monitoring end equipment can also actively upload air quality parameters to the cloud server; the air quality parameter of the cloud server can be obtained by the purifying equipment in real time, and the purifying equipment can further adjust the operation related parameter based on the air quality parameter, such as controlling the air quantity or controlling the operation state.

In addition, the cloud server can store and read data, and then the user can check the running state of the system through the APP.

It is thus clear that through adopting above-mentioned scheme, just can set up monitoring end equipment and the clarification plant of different positions department in same space respectively and handle based on among the distributed purification system, can carry out air quality monitoring by monitoring end equipment, and then confirm the operation relevant control according to the air quality parameter by clarification plant. So, monitoring end equipment that just can set up different clarification plant and bind in the different spaces in multiple space to all use same clarification plant to carry out air purification in order to bring the great and great problem of noise of amount of wind in avoiding a plurality of spaces, and, owing to separately set up monitoring end equipment and clarification plant, make all have corresponding clarification plant in each space, consequently guaranteed the purifying effect in each space.

In the description herein, reference to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the application. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise.

The above description is only for the specific embodiments of the present application, but the scope of the present application is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present application, and shall be covered by the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (15)

1. A distributed purification system, the system comprising: the system comprises at least one monitoring end device and at least one purifying device; different purifying devices in the at least one purifying device are respectively arranged in different spaces, different monitoring end devices in the at least one monitoring end device are respectively arranged in different spaces, and the purifying devices and the monitoring end devices which are in binding relation are arranged at different positions in the same space; wherein the content of the first and second substances,

the monitoring end equipment is used for detecting the air quality parameters of the space and uploading the air quality parameters of the space;

and the purifying equipment is used for determining operation related parameters according to the air quality parameters of the space where the purifying equipment is located, which are uploaded by the monitoring end equipment with the binding relationship with the purifying equipment, and performing air purification treatment on the space where the purifying equipment is located based on the operation mode and the operation related parameters.

2. The distributed purification system of claim 1, further comprising: a cloud server; wherein the content of the first and second substances,

the cloud server is used for receiving the air quality parameters of the space where the monitoring end equipment is located, which are reported by each monitoring end equipment in at least one monitoring end equipment;

correspondingly, the monitoring end equipment is specifically used for sending the air quality parameters of the space to the cloud server;

the purifying equipment is specifically used for acquiring air quality parameters uploaded by monitoring end equipment which has a binding relationship with the purifying equipment from the cloud server.

3. The distributed purification system of claim 1 or 2,

and the purifying equipment is further used for continuously and periodically acquiring new air quality parameters of the located space detected by the corresponding monitoring end equipment after the located space is subjected to air purification treatment based on the determined operation mode and the operation related parameters, adjusting the operation related parameters based on the new air quality parameters of the located space, and performing air purification treatment on the located space based on the adjusted operation related parameters.

4. The distributed purification system of claim 3,

the purifying equipment is further used for adjusting operation related parameters to be a lowest purifying gear or a standby state when the air quality in the space where the purifying equipment is located is determined to reach the preset quality based on the air quality parameters.

5. The distributed purification system of claim 2, further comprising:

the application control layer equipment is used for acquiring and displaying the running state of the at least one purifying equipment and the air quality condition of the at least one space; the cloud server is used for acquiring instruction information; wherein, the instruction information comprises a system purification mode;

correspondingly, the cloud server is further used for determining the purifying equipment for executing the purifying treatment and the corresponding monitoring end equipment according to the system purifying mode in the instruction information.

6. The distributed scrubbing system of any one of claims 1, 2 or 5, further comprising:

the operation and maintenance service layer equipment is used for carrying out fault detection and service life detection on at least one purifying device through the data stored in the cloud server; and pushing reminding information to the application control layer equipment.

7. The distributed decontamination system of claim 2, wherein the cloud server comprises:

the third communication interface is used for receiving the space quality parameters of the space where the monitoring end equipment is uploaded; and providing space quality parameters of the space where the purifying equipment is located for the purifying equipment.

8. The distributed decontamination system of claim 5, wherein the application control layer device comprises:

the fourth communication interface is used for acquiring the running state of at least one piece of purification equipment and the air quality condition of at least one space; transmitting the acquired instruction information to a cloud server;

and the display unit is used for displaying the running state of the at least one purifying device and the air quality condition of the at least one space.

9. The distributed decontamination system of claim 6, wherein the operation and maintenance service layer device comprises:

the fifth communication interface is used for acquiring data stored by the cloud server; pushing reminding information to the application control layer equipment;

the fifth processor is used for carrying out fault detection and service life detection on at least one purifying device according to the data of the cloud server; and generating the reminding information.

10. The purifying equipment is characterized in that the purifying equipment is equipment in a distributed purifying system, and monitoring end equipment which is located at different positions in the same space and has a binding relationship with the purifying equipment exists; the purification apparatus includes:

the first communication interface is used for acquiring the air quality parameters of the space where the monitoring end equipment with the binding relationship with the first communication interface is located;

and the first processor is used for determining operation related parameters according to the air quality parameters of the space and carrying out air purification treatment on the space based on the operation mode and the operation related parameters.

11. The purifying apparatus according to claim 10, wherein the first communication interface is configured to obtain, from a cloud server, the air quality parameter of the space where the monitoring-end device is located, which is reported by the monitoring-end device in the binding relationship with the cloud server.

12. The monitoring end equipment is characterized in that the monitoring end equipment is equipment in a distributed purification system, and the monitoring end equipment has purification equipment which is located at different positions in the same space and has a binding relationship with the monitoring end equipment; the monitoring end equipment comprises:

the monitoring unit is used for detecting the air quality parameter of the space;

and the second communication interface is used for uploading the air quality parameters of the space.

13. A distributed purification method is characterized by being applied to a distributed purification system, wherein the distributed purification system comprises at least one monitoring end device and at least one purification device; different purifying devices in the at least one purifying device are respectively arranged in different spaces, different monitoring end devices in the at least one monitoring end device are respectively arranged in different spaces, and the purifying devices and the monitoring end devices which are in binding relation are arranged at different positions in the same space; the method comprises the following steps:

the at least one monitoring end device detects the air quality parameters of the space where the monitoring end device is located and uploads the air quality parameters of the space where the monitoring end device is located;

the at least one purifying device determines operation related parameters according to the air quality parameters of the space where the purifying device is located and uploaded by the monitoring end device which has a binding relationship with the purifying device;

and the at least one purifying device is used for carrying out air purification treatment on the space based on the operation mode and the operation related parameters respectively.

14. A distributed purification method is characterized in that the method is applied to purification equipment, the purification equipment is equipment in a distributed purification system, the purification equipment is provided with monitoring end equipment with binding relationship, and the purification equipment and the monitoring end equipment with the binding relationship are positioned at different positions in the same space; the method comprises the following steps:

the purification equipment acquires the air quality parameters of the space uploaded by the monitoring end equipment in a binding relationship with the purification equipment;

the purification equipment determines operation related parameters according to the air quality parameters of the space;

and the purifying equipment carries out air purification treatment on the space based on the operation mode and the operation related parameters.

15. A distributed purification method is characterized in that the method is applied to monitoring end equipment, the monitoring end equipment is equipment in a distributed purification system, the monitoring end equipment is provided with purification equipment with binding relationship, and the purification equipment and the monitoring end equipment with the binding relationship are positioned at different positions in the same space; the method comprises the following steps:

the monitoring end equipment detects the air quality parameter of the space where the monitoring end equipment is located;

and the monitoring end equipment uploads the air quality parameters of the space where the monitoring end equipment is located.

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