CN113834109A - Networking configuration method and system for central range hood - Google Patents

Abstract

The invention provides a networking configuration method and a networking configuration system for a central range hood, which comprise the following steps: connecting a configuration tool to each power distribution valve in at least one power distribution valve; respectively sending the altitude information of each power distribution valve acquired based on the configuration tool to the corresponding power distribution valve; the altitude information corresponding to each power distribution valve and the self code of each power distribution valve are sent to a central range hood host through at least one power distribution valve; carrying out floor coding on at least one power distribution valve according to a preset coding rule based on the altitude information corresponding to each power distribution valve and the self-coding to obtain floor coding information of each power distribution valve; and transmitting the floor code information of each power distribution valve to the corresponding power distribution valve, and storing the floor code information in a storage unit of the corresponding power distribution valve. The invention solves the technical problems of complex configuration flow and easy occurrence of configuration entry errors in the prior art.

Description

Networking configuration method and system for central range hood

Technical Field

The invention relates to the technical field of networking configuration of a central range hood, in particular to a networking configuration method and a networking configuration system of a central range hood.

Background

The current networking configuration of the central range hood needs to configure a tool, and the writing-in of configuration parameters such as communication frequency points, floors and the like is realized through the reading and writing of a wireless module on the tool. The networking configuration mode of the existing central range hood needs to realize system networking through manual configuration of a configuration tool, and the mode has some problems, firstly, tool operation and configuration processes need to be trained on installation personnel, secondly, parameter entry errors exist in the process of tool entry, and finally 433, a wireless scheme of LoRa modulation exists, and if a plurality of terminals all have the condition of mutual interference when parameters are written in configuration. Existing solutions eventually lead to a need for troubleshooting in case of configuration logging errors.

Disclosure of Invention

In view of the above, the present invention provides a networking configuration method and system for a central range hood, so as to alleviate the technical problems of complex configuration process and easy occurrence of configuration entry errors in the prior art.

In a first aspect, an embodiment of the present invention provides a central extractor hood networking configuration method, which is applied to a central extractor hood system, where the central extractor hood system includes a central extractor hood host and at least one power distribution valve; the central range hood main engine is connected with the at least one power distribution valve through a preset network; the method comprises the following steps: connecting a configuration tool to each power distribution valve in the at least one power distribution valve; the configuration tool is a device for detecting the altitude; respectively sending the altitude information of each power distribution valve acquired based on the configuration tool to the corresponding power distribution valve; the altitude information corresponding to each power distribution valve and the self code of each power distribution valve are sent to the central range hood host through the at least one power distribution valve; carrying out floor coding on the at least one power distribution valve according to a preset coding rule based on the altitude information corresponding to each power distribution valve and the self-coding to obtain floor coding information of each power distribution valve; and transmitting the floor code information of each power distribution valve to the corresponding power distribution valve, and storing the floor code information in a storage unit of the corresponding power distribution valve.

Further, the step of respectively sending the altitude information of each power distribution valve acquired based on the configuration tool to the corresponding power distribution valve comprises the following steps: acquiring atmospheric pressure value information of the position of the target power distribution valve based on the configuration tool; the target power distribution valve is one of the at least one power distribution valve; detecting whether the atmospheric pressure value information has large-amplitude fluctuation or not based on the configuration tool; if not, determining altitude information of the target power distribution valve based on the atmospheric pressure value; transmitting altitude information of the target power distribution valve to the target power distribution valve.

Further, the preset encoding rule includes any one of: arranging codes according to the sequence of altitude information from low to high; arranging codes according to the altitude information from high to low; and after taking the intermediate value according to the altitude information, sequentially arranging the codes from the intermediate value upwards and downwards respectively.

Further, after floor coding is performed on the at least one power distribution valve according to a preset coding rule based on the altitude information corresponding to each power distribution valve and the self-coding, the method further comprises: checking whether the number of codes per se of each power distribution valve is equal to a preset number or not, and whether the number of altitude information corresponding to each power distribution valve is equal to the preset number or not; and if not, prompting configuration error information.

In a second aspect, an embodiment of the present invention further provides a central range hood networking configuration system, including: the central range hood main machine is provided with a tool and at least one power distribution valve; the central range hood main engine is connected with the at least one power distribution valve through a preset network; the configuration tool is a device for detecting the altitude; the configuration tool is used for being connected to each power distribution valve in the at least one power distribution valve, acquiring altitude information of each power distribution valve and respectively sending the altitude information to the corresponding power distribution valve; the power distribution valve is used for sending the altitude information and the self code of each power distribution valve to the central range hood host; the central range hood host is used for carrying out floor coding on at least one power distribution valve according to a preset coding rule based on the altitude information corresponding to each power distribution valve and the self-coding to obtain floor coding information of each power distribution valve; the central range hood main unit is also used for sending the floor coding information of each power distribution valve to the corresponding power distribution valve.

Further, the configuration tool comprises: the device comprises a communication module, a prompt module and a sensor module; the sensor module is used for acquiring atmospheric pressure value information of the position where the configuration tool is located; the prompting module is used for displaying the atmospheric pressure value information; and the communication module is used for sending the atmospheric pressure value information to the power distribution valve.

Further, the prompt module is further configured to send a sending success prompt tone after the communication module successfully sends the atmospheric pressure value information to the power distribution valve.

In a third aspect, an embodiment of the present invention further provides a central range hood networking configuration system, including: the system comprises a central range hood main machine, a cloud platform, a configuration tool and at least one power distribution valve; the central range hood host and the at least one power distribution valve are connected with the cloud platform through a preset network; the configuration tool is a device for detecting the altitude; the configuration tool is used for being connected to each power distribution valve in the at least one power distribution valve, acquiring altitude information of each power distribution valve and respectively sending the altitude information to the corresponding power distribution valve; the at least one power distribution valve is used for sending the altitude information and the self code of each power distribution valve to the cloud platform; the cloud platform is used for carrying out floor coding on at least one power distribution valve according to a preset coding rule based on the altitude information corresponding to each power distribution valve and the self-coding to obtain floor coding information of each power distribution valve; the cloud platform is further used for sending the floor coding information of each power distribution valve to the corresponding power distribution valve.

Further, the configuration tool is connected to the at least one power distribution valve through a wired connection.

In a fourth aspect, the present invention further provides a computer-readable medium having non-volatile program code executable by a processor, where the program code causes the processor to execute the method according to the first aspect.

The invention aims to provide a networking configuration method and a networking configuration system for a central range hood, wherein altitude information of the position of a power distribution valve is obtained through a configuration tool and then reported to a central range hood host or a cloud platform, and the central range hood host or the cloud platform distributes floor heights to the power distribution valve according to the altitude information of each power distribution valve, so that the technical effect of automatic floor number configuration is realized, and the technical problems of complex configuration flow and easiness in configuration entry errors in the prior art are solved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a flowchart of a central range hood networking configuration method provided by an embodiment of the present invention;

fig. 2 is a schematic diagram of a central range hood networking configuration system according to an embodiment of the present invention;

fig. 3 is a schematic diagram of a configuration tool according to an embodiment of the present invention;

fig. 4 is a schematic diagram of another central extractor hood networking configuration system according to an embodiment of the present invention.

Icon:

10-central range hood host; 20-configuring a tool; 30-at least one power distribution valve; 40-a cloud platform; 21-a communication module; 22-a prompt module; 23-a sensor module; and 24, a main control chip.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. 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 invention.

The first embodiment is as follows:

fig. 1 is a flowchart of a central extractor hood networking configuration method according to an embodiment of the present invention, and the method is applied to a central extractor hood system. The central range hood system comprises a central range hood main machine and at least one power distribution valve; the central range hood main machine is connected with at least one power distribution valve through a preset network. As shown in fig. 1, the method provided in the embodiment of the present invention specifically includes the following steps:

step S102, connecting a configuration tool to each power distribution valve in at least one power distribution valve; the configuration frock is the device that detects the altitude.

And step S104, respectively sending the altitude information of each power distribution valve acquired based on the configuration tool to the corresponding power distribution valve.

And step S106, transmitting the altitude information corresponding to each power distribution valve and the self code of each power distribution valve to the central range hood host through at least one power distribution valve.

And S108, carrying out floor coding on at least one power distribution valve according to a preset coding rule based on the altitude information corresponding to each power distribution valve and the self-coding to obtain floor coding information of each power distribution valve.

Optionally, the preset encoding rule includes any one of:

arranging codes according to the sequence of altitude information from low to high;

arranging codes according to the altitude information from high to low;

and after taking the intermediate value according to the altitude information, sequentially arranging the codes from the intermediate value upwards and downwards respectively.

Optionally, the floor information of each power distribution valve is determined by sequencing the altitude information corresponding to each power distribution valve, so that the floor coding operation is performed on each power distribution valve to obtain the floor coding information of each power distribution valve.

And step S110, transmitting the floor code information of each power distribution valve to the corresponding power distribution valve, and storing the floor code information in the storage unit of the corresponding power distribution valve.

The invention aims to provide a networking configuration method of a central range hood, which is characterized in that altitude information of the position of a power distribution valve is obtained through a configuration tool and then reported to a central range hood host or a cloud platform, and the central range hood host or the cloud platform distributes floor heights to the power distribution valves according to the altitude information of each power distribution valve, so that the technical effect of automatic floor number configuration is realized, and the technical problems of complex configuration flow and easy occurrence of configuration entry errors in the prior art are solved.

Optionally, step S104 specifically includes the following steps:

step S1041, acquiring atmospheric pressure value information of a position where a target power distribution valve is located based on a configuration tool; the target power distribution valve is one of the at least one power distribution valves.

And step S1042, detecting whether the atmospheric pressure value information has large fluctuation or not based on the configuration tool. If yes, executing step S1043; if not, step S1044 is executed.

And S1043, continuously detecting the fluctuation range of the atmospheric pressure value obtained by the configuration tool.

In step S1044, altitude information of the target power distribution valve is determined based on the atmospheric pressure value.

Step S1045, transmitting the altitude information of the target power distribution valve to the target power distribution valve.

In the embodiment of the invention, the atmospheric pressure value obtained by the configuration tool possibly has the condition of large numerical fluctuation, the reading of the atmospheric pressure value of the configuration tool needs to be monitored, and the atmospheric pressure value at the position of the power distribution valve is obtained under the condition that the fluctuation of the obtained atmospheric pressure value is determined to be in a stable range, so that the reliability of the altitude information of the power distribution valve is ensured.

In an embodiment of the invention, the code of each power distribution valve is sent to the central extractor hood main unit through at least one power distribution valve.

Optionally, the method provided in the embodiment of the present invention further includes verifying the acquired information; specifically, whether the number of codes of each power distribution valve is equal to a preset number or not and whether the number of altitude information corresponding to each power distribution valve is equal to the preset number or not are checked; and if not, prompting configuration error information.

In the embodiment of the invention, the network connection between the power distribution valve and the central range hood host can be realized by scanning the two-dimensional code on the power distribution valve. Specifically, the embodiment of the present invention provides a valve method, further including the following steps:

s1, electrifying the power distribution valve for starting;

s2, scanning the two-dimensional code on the power distribution valve to realize the network connection between the power distribution valve and the central range hood host;

s3, connecting the configuration tool with a power distribution valve, and starting the configuration tool (the automatic configuration tool comprises a signal acquisition module);

s4, configuring a tool to monitor whether the acquired atmospheric pressure value has large fluctuation or not, if so, continuing to monitor, and if not, recording the current atmospheric pressure value and converting the current atmospheric pressure value into an altitude value;

s5, the configuration tool transmits the altitude value to the power distribution valve and prompts the success of transmission;

s6, the power distribution valve transmits the code and the altitude value to the central range hood host;

s7, after the configuration of all floors is completed, the central range hood host checks whether the number of the received codes and the number of the altitude values are equal to the preset number, if not, the system is in error, and the system reports the error to the cloud platform;

s8, if yes, carrying out floor numbering on the power distribution valves of each code according to the altitude height value, and sending the floor numbering to the power distribution valves;

and S9, the power distribution valve stores the floor code information, and the automatic floor configuration is completed.

According to the networking configuration method of the central range hood provided by the embodiment of the invention, the configuration tool is used for acquiring the altitude information of the position of the power distribution valve on each floor, then the altitude information of all the power distribution valves is sequenced, the floor information of each power distribution valve is further judged, and then the power distribution valves can be subjected to floor numbering and automatic configuration.

Example two:

fig. 2 is a schematic diagram of a networking configuration system of a central range hood according to an embodiment of the present invention. As shown in fig. 2, the system includes: a central range hood main body 10, a configuration tool 20 and at least one power distribution valve 30; the central range hood main body 10 is connected with at least one power distribution valve 30 through a preset network; tooling 20 is configured as a device for detecting altitude.

Specifically, the tool 20 is configured to be connected to each power distribution valve of the at least one power distribution valve 30, obtain altitude information of each power distribution valve, and send the altitude information to the corresponding power distribution valve.

And the power distribution valve 30 is used for sending the altitude information and the self code to the central range hood main machine 10.

And the central range hood host 10 is used for carrying out floor coding on at least one power distribution valve 30 according to a preset coding rule based on the altitude information and the self code corresponding to each power distribution valve to obtain the floor coding information of each power distribution valve.

The central extractor hood host 10 is further configured to send the floor coding information of each power distribution valve to the corresponding power distribution valve.

The invention aims to provide a central range hood networking configuration system, which is characterized in that altitude information of the position of a power distribution valve is obtained through a configuration tool and then reported to a central range hood host or a cloud platform, and the central range hood host or the cloud platform distributes floor heights to the power distribution valve according to the altitude information of each power distribution valve, so that the technical effect of automatic floor number configuration is realized, and the technical problems of complex configuration flow and easiness in configuration entry errors in the prior art are solved.

Fig. 3 is a schematic diagram of a configuration tool according to an embodiment of the present invention. As shown in fig. 3, the configuration tool 20 includes: the system comprises a communication module 21, a prompt module 22, a sensor module 23 and a main control chip 24.

Specifically, the sensor module 23 is configured to obtain atmospheric pressure value information of a position where the configuration tool is located;

the prompting module 22 is used for displaying the atmospheric pressure value information;

the communication module 21 is used for sending the atmospheric pressure value information to the power distribution valve;

and the prompt module 22 is further configured to send a sending success prompt tone after the communication module 21 successfully sends the atmospheric pressure value information to the power distribution valve.

In the embodiment of the invention, the configuration tool can be divided into three major parts according to functions, namely a communication module 21, a prompt module 22 and a sensor module 23. The communication module 21 is used for establishing communication with the power distribution valve and writing parameters; the prompting module 22 can prompt whether the sensor data is stable and whether the parameter writing is successful, or can be other modules with prompting function, such as a buzzer; the sensor module 23 is used for detecting the atmospheric pressure value of the position, and further obtaining the sea level height, the ground height and the like of the position.

Example three:

fig. 4 is a schematic diagram of another central range hood networking configuration system provided in an embodiment of the present invention. As shown in fig. 4, the system includes: the central range hood comprises a central range hood main machine 10, a cloud platform 40, a configuration tool 20 and at least one power distribution valve 30; the central range hood host 10 and the at least one power distribution valve 30 are connected with the cloud platform 40 through a preset network; tooling 20 is configured as a device for detecting altitude.

The configuration tool 20 is configured to be connected to each power distribution valve of the at least one power distribution valve 30, obtain altitude information of each power distribution valve, and send the altitude information to the corresponding power distribution valve.

At least one power distribution valve 30 for transmitting altitude information and its own code of each power distribution valve to the cloud platform 40.

And the cloud platform 40 is used for carrying out floor coding on at least one power distribution valve 30 according to a preset coding rule based on the altitude information and the self code corresponding to each power distribution valve to obtain the floor coding information of each power distribution valve.

The cloud platform 40 is further configured to send the floor coding information of each power distribution valve to the corresponding power distribution valve.

The invention aims to provide a central range hood networking configuration system, which is characterized in that altitude information of the position of a power distribution valve is obtained through a configuration tool and then reported to a central range hood host or a cloud platform, and the central range hood host or the cloud platform distributes floor heights to the power distribution valve according to the altitude information of each power distribution valve, so that the technical effect of automatic floor number configuration is realized, and the technical problems of complex configuration flow and easiness in configuration entry errors in the prior art are solved.

Optionally, the tool 20 is configured to access at least one power distribution valve 30 via a wired connection.

The embodiment of the present invention further provides an electronic device, which includes a memory, a processor, and a computer program stored in the memory and capable of running on the processor, and when the processor executes the computer program, the steps of the method in the first embodiment are implemented.

The embodiment of the invention also provides a computer readable medium with a non-volatile program code executable by a processor, wherein the program code causes the processor to execute the method in the first embodiment.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. A central range hood networking configuration method is applied to a central range hood system, and the central range hood system comprises a central range hood main machine and at least one power distribution valve; the central range hood main engine is connected with the at least one power distribution valve through a preset network; characterized in that the method comprises:

connecting a configuration tool to each power distribution valve in the at least one power distribution valve; the configuration tool is a device for detecting the altitude;

respectively sending the altitude information of each power distribution valve acquired based on the configuration tool to the corresponding power distribution valve;

the altitude information corresponding to each power distribution valve and the self code of each power distribution valve are sent to the central range hood host through the at least one power distribution valve;

carrying out floor coding on the at least one power distribution valve according to a preset coding rule based on the altitude information corresponding to each power distribution valve and the self-coding to obtain floor coding information of each power distribution valve;

and transmitting the floor code information of each power distribution valve to the corresponding power distribution valve, and storing the floor code information in a storage unit of the corresponding power distribution valve.

2. The method of claim 1, wherein the step of sending the altitude information of each power distribution valve acquired based on the configuration tool to the corresponding power distribution valve respectively comprises the steps of:

acquiring atmospheric pressure value information of the position of the target power distribution valve based on the configuration tool; the target power distribution valve is one of the at least one power distribution valve;

detecting whether the atmospheric pressure value information has large-amplitude fluctuation or not based on the configuration tool;

if not, determining altitude information of the target power distribution valve based on the atmospheric pressure value;

transmitting altitude information of the target power distribution valve to the target power distribution valve.

3. The method according to claim 1, wherein the preset encoding rule comprises any one of:

arranging codes according to the sequence of altitude information from low to high;

arranging codes according to the altitude information from high to low;

and after taking the intermediate value according to the altitude information, sequentially arranging the codes from the intermediate value upwards and downwards respectively.

4. The method of claim 1, wherein after floor coding the at least one power distribution valve according to a preset coding rule based on the altitude information corresponding to each power distribution valve and the self-code, the method further comprises:

checking whether the number of codes per se of each power distribution valve is equal to a preset number or not, and whether the number of altitude information corresponding to each power distribution valve is equal to the preset number or not;

and if not, prompting configuration error information.

5. A central range hood networking configuration system is characterized by comprising: the central range hood main machine is provided with a tool and at least one power distribution valve; the central range hood main engine is connected with the at least one power distribution valve through a preset network; the configuration tool is a device for detecting the altitude;

the configuration tool is used for being connected to each power distribution valve in the at least one power distribution valve, acquiring altitude information of each power distribution valve and respectively sending the altitude information to the corresponding power distribution valve;

the power distribution valve is used for sending the altitude information and the self code of each power distribution valve to the central range hood host;

the central range hood host is used for carrying out floor coding on at least one power distribution valve according to a preset coding rule based on the altitude information corresponding to each power distribution valve and the self-coding to obtain floor coding information of each power distribution valve;

the central range hood main unit is also used for sending the floor coding information of each power distribution valve to the corresponding power distribution valve.

6. The system of claim 5, wherein the configuration tool comprises: the device comprises a communication module, a prompt module and a sensor module;

the sensor module is used for acquiring atmospheric pressure value information of the position where the configuration tool is located;

the prompting module is used for displaying the atmospheric pressure value information;

and the communication module is used for sending the atmospheric pressure value information to the power distribution valve.

7. The system of claim 6, wherein the prompt module is further configured to send a transmission success prompt after the communication module successfully sends the barometric pressure information to the power distribution valve.

8. A central range hood networking configuration system is characterized by comprising: the system comprises a central range hood main machine, a cloud platform, a configuration tool and at least one power distribution valve; the central range hood host and the at least one power distribution valve are connected with the cloud platform through a preset network; the configuration tool is a device for detecting the altitude;

the configuration tool is used for being connected to each power distribution valve in the at least one power distribution valve, acquiring altitude information of each power distribution valve and respectively sending the altitude information to the corresponding power distribution valve;

the at least one power distribution valve is used for sending the altitude information and the self code of each power distribution valve to the cloud platform;

the cloud platform is used for carrying out floor coding on at least one power distribution valve according to a preset coding rule based on the altitude information corresponding to each power distribution valve and the self-coding to obtain floor coding information of each power distribution valve;

the cloud platform is further used for sending the floor coding information of each power distribution valve to the corresponding power distribution valve.

9. The system of claim 8, wherein the configuration tool accesses the at least one power distribution valve via a wired connection.

10. A computer-readable medium having non-volatile program code executable by a processor, wherein the program code causes the processor to perform the method of any of claims 1-4.

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