阅读说明：本技术 母线槽远程温湿度实时测控、反馈与控制系统 (Bus duct remote temperature and humidity real-time measurement, feedback and control system ) 是由 张金荣 于 2021-07-14 设计创作，主要内容包括：本发明公开了母线槽远程温湿度实时测控、反馈与控制系统,包括母线槽、湿度感应器和温度感应器；湿度感应器和温度感应器分别感应母线槽内部的湿度和温度,从而将信息反馈给采集整合模块,采集整合模块将信息反馈给分析模块,最后分析模块将信息传输给控制模块。本发明母线槽远程温湿度实时测控、反馈与控制系统,通过湿度感应器和温度感应器分别感应母线槽内部的湿度和温度,从而将信息反馈给采集整合模块；通过分析模块用于提取输入采集整合模块中的特征,作为分析模块的输入。(The invention discloses a bus duct remote temperature and humidity real-time measurement, feedback and control system, which comprises a bus duct, a humidity sensor and a temperature sensor, wherein the bus duct is provided with a temperature sensor and a temperature sensor; humidity inductor and temperature-sensing ware respond to the inside humidity and the temperature of bus duct respectively to integrate the module with information feedback collection, gather and integrate the module and feed back information to analysis module, analysis module gives control module with information transmission at last. According to the bus duct remote temperature and humidity real-time measurement and control, feedback and control system, the humidity and the temperature inside the bus duct are respectively sensed through the humidity sensor and the temperature sensor, so that information is fed back to the acquisition integration module; the analysis module is used for extracting the characteristics in the input acquisition integration module and taking the characteristics as the input of the analysis module.)

1. The bus duct remote temperature and humidity real-time measurement and control, feedback and control system is characterized by comprising a bus duct, a humidity sensor and a temperature sensor; the humidity sensor and the temperature sensor respectively sense the humidity and the temperature inside the bus duct, so that information is fed back to the acquisition and integration module, the acquisition and integration module feeds back the information to the analysis module, and finally the analysis module transmits the information to the control module;

the specific method for collecting by the collection and integration module comprises the following steps:

s1: coding the feedback information through a coder, then forming a first sub-stream and a second sub-stream, then designing the first sub-stream and the second sub-stream, and fragmenting the data through designing a data fragmentation selection algorithm;

s2: based on machine learning, carrying out encryption processing on the fragmented data, and then distributing data to each sub-stream in turn;

s3: and integrating the sub-stream distribution data, and finishing the integration.

2. The bus duct remote temperature and humidity real-time measurement, control, feedback and control system according to claim 1, wherein the analysis module is used for extracting features in the input acquisition integration module as input of the analysis module; the analysis module outputs 4-dimensional vectors by adopting 16 to 32 different information symbols, then performs analysis processing on the data, feeds back the information to the control module when the analysis data is larger than a preset threshold value, and stores the information when the analysis data is smaller than the preset threshold value.

3. The bus duct remote temperature and humidity real-time measurement, control, feedback and control system according to claim 2, wherein the analysis data is smaller than a preset threshold, and the information is stored and processed by a storage module.

4. The bus duct remote temperature and humidity real-time measurement, control, feedback and control system according to claim 1, wherein the results processed by the acquisition and integration module can be spliced to convert the results into a JSON string format, and each parameter item input by a user, the JSON string, test time and the like are combined into one piece of data, and then the data is inserted into a database, so that each result is stored.

5. The bus duct remote temperature and humidity real-time measurement, control, feedback and control system according to claim 1, wherein the control module transmits information data to the image module, and the image module is played and stored by a mobile phone terminal.

6. The bus duct remote temperature and humidity real-time measurement, control, feedback and control system according to claim 5, wherein the image module can form image sequences C1, C2,. and.. cne; each of the small images C1, C2, the.

7. The bus duct remote temperature and humidity real-time measurement, control, feedback and control system according to claim 1, wherein the control module is further connected with a monitoring module, and the monitoring module adopts a camera for collection and camera shooting.

8. The bus duct remote temperature and humidity real-time measurement, control, feedback and control system according to claim 7, wherein the camera is processed by a high-definition camera.

9. The bus duct remote temperature and humidity real-time measurement, control, feedback and control system according to claim 1, wherein the control module is further connected with an alarm module for alarm information processing.

Technical Field

The invention relates to the technical field of bus duct remote measurement and control, in particular to a bus duct remote temperature and humidity real-time measurement and control, feedback and control system.

Background

The bus duct is a closed metal device formed from copper and aluminium bus posts, and is used for distributing large power for every element of dispersion system. Wire and cable have been increasingly replaced in indoor low voltage power transmission mains engineering projects. With the emergence of modern engineering facilities and equipment, the power consumption of various industries is increased rapidly, particularly, the appearance of numerous high-rise buildings and large-scale factory workshops, the traditional cable serving as a power transmission lead cannot meet the requirement in a large-current transmission system, and the parallel connection of multiple cables brings inconvenience to on-site installation, construction and connection.

The temperature and humidity of the bus duct in the prior art can not be measured and controlled in real time and fed back, and meanwhile, the control is carried out, so that the service efficiency of the bus duct is reduced, and further improvement processing is needed on the basis.

Disclosure of Invention

The invention aims to provide a bus duct remote temperature and humidity real-time measurement, feedback and control system to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

the bus duct remote temperature and humidity real-time measurement, feedback and control system comprises a bus duct, a humidity sensor and a temperature sensor; the humidity sensor and the temperature sensor respectively sense the humidity and the temperature inside the bus duct, so that information is fed back to the acquisition and integration module, the acquisition and integration module feeds back the information to the analysis module, and finally the analysis module transmits the information to the control module;

the specific method for collecting by the collection and integration module comprises the following steps:

s1: coding the feedback information through a coder, then forming a first sub-stream and a second sub-stream, then designing the first sub-stream and the second sub-stream, and fragmenting the data through designing a data fragmentation selection algorithm;

s2: based on machine learning, carrying out encryption processing on the fragmented data, and then distributing data to each sub-stream in turn;

s3: and integrating the sub-stream distribution data, and finishing the integration.

Preferably, the analysis module is used for extracting the features in the input acquisition integration module as the input of the analysis module; the analysis module outputs 4-dimensional vectors by adopting 16 to 32 different information symbols, then performs analysis processing on the data, feeds back the information to the control module when the analysis data is larger than a preset threshold value, and stores the information when the analysis data is smaller than the preset threshold value.

Preferably, the analysis data is smaller than a preset threshold, and the information is stored by a storage module.

Preferably, the results processed by the acquisition and integration module may be spliced to convert the results into a JSON string format, and each parameter item input by the user, the JSON string, the test time, and the like are combined into one piece of data, and then the data is inserted into the database, so that each result is stored.

Preferably, the control module transmits the information data to the image module, and the image module is played and stored by adopting a mobile phone terminal.

Preferably, the image modules may form a sequence of images C1, C2, ·.., Cn; each of the small images C1, C2, the.

Preferably, the control module is further connected with a monitoring module, and the monitoring module adopts a camera to collect and shoot images.

Preferably, the camera is processed by a high-definition camera.

Preferably, the control module is further connected with an alarm module for processing alarm information.

Compared with the prior art, the invention has the beneficial effects that:

according to the bus duct remote temperature and humidity real-time measurement and control, feedback and control system, the humidity and the temperature inside the bus duct are respectively sensed through the humidity sensor and the temperature sensor, so that information is fed back to the acquisition integration module; the analysis module is used for extracting the characteristics in the input acquisition integration module and taking the characteristics as the input of the analysis module; the analysis module outputs 4-dimensional vectors by adopting 16 to 32 different information symbols, then performs analysis processing on the data, feeds back the information to the control module when the analysis data is larger than a preset threshold value, and stores the information when the analysis data is smaller than the preset threshold value; the results processed by the acquisition and integration module can be spliced to be converted into a JSON string format, each parameter item input by a user, the JSON string, test time and the like are combined into one piece of data, and then the data is inserted into the database, so that each result is stored.

Drawings

FIG. 1 is a schematic diagram of the system of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of 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 invention.

Referring to fig. 1, in the present invention, a bus duct remote temperature and humidity real-time measurement, feedback and control system includes a bus duct, a humidity sensor and a temperature sensor; the humidity sensor and the temperature sensor respectively sense the humidity and the temperature inside the bus duct, so that information is fed back to the acquisition and integration module, the acquisition and integration module feeds back the information to the analysis module, and finally the analysis module transmits the information to the control module;

the specific method for collecting by the collection and integration module comprises the following steps:

s1: coding the feedback information through a coder, then forming a first sub-stream and a second sub-stream, then designing the first sub-stream and the second sub-stream, and fragmenting the data through designing a data fragmentation selection algorithm;

s2: based on machine learning, carrying out encryption processing on the fragmented data, and then distributing data to each sub-stream in turn;

s3: and integrating the sub-stream distribution data, and finishing the integration.

The analysis module of the embodiment is used for extracting the features in the input acquisition integration module as the input of the analysis module; the analysis module outputs 4-dimensional vectors by adopting 16 to 32 different information symbols, then performs analysis processing on the data, feeds back the information to the control module when the analysis data is larger than a preset threshold value, and stores the information when the analysis data is smaller than the preset threshold value.

In this embodiment, the analysis data is smaller than the preset threshold, and the information is stored and processed by the storage module.

The result processed by the acquisition and integration module in this embodiment may be spliced to convert the result into a JSON string format, and each parameter item input by the user, the JSON string, the test time, and the like are merged into one piece of data, and then the data is inserted into the database, so that each result is saved.

The control module of the embodiment transmits the information data to the image module, and the image module is played and stored by adopting a mobile phone terminal.

The image modules of the present embodiment may form image sequences C1, C2, ·.., Cn; each of the small images C1, C2, the.

The control module of this embodiment still is connected with the monitor module, and the monitor module adopts the camera to gather and make a video recording.

The camera of this embodiment adopts high definition digtal camera to handle.

The control module of the embodiment is further connected with the alarm module and used for processing alarm information.

Referring to fig. 1, in the present invention, a bus duct remote temperature and humidity real-time measurement, feedback and control system includes a bus duct, a humidity sensor and a temperature sensor; the humidity sensor and the temperature sensor respectively sense the humidity and the temperature inside the bus duct, so that information is fed back to the acquisition and integration module, the acquisition and integration module feeds back the information to the analysis module, and finally the analysis module transmits the information to the control module;

the specific method for collecting by the collection and integration module comprises the following steps:

s1: coding the feedback information through a coder, then forming a first sub-stream and a second sub-stream, then designing the first sub-stream and the second sub-stream, and fragmenting the data through designing a data fragmentation selection algorithm;

s2: based on machine learning, carrying out encryption processing on the fragmented data, and then distributing data to each sub-stream in turn;

s3: and integrating the sub-stream distribution data, and finishing the integration.

The analysis module of the embodiment is used for extracting the features in the input acquisition integration module as the input of the analysis module; the analysis module outputs 4-dimensional vectors by adopting 16 to 32 different information symbols, then performs analysis processing on the data, feeds back the information to the control module when the analysis data is larger than a preset threshold value, and stores the information when the analysis data is smaller than the preset threshold value.

In this embodiment, the analysis data is smaller than the preset threshold, and the information is stored and processed by the storage module.

The result processed by the acquisition and integration module in this embodiment may be spliced to convert the result into a JSON string format, and each parameter item input by the user, the JSON string, the test time, and the like are merged into one piece of data, and then the data is inserted into the database, so that each result is saved.

The control module of the embodiment transmits the information data to the image module, and the image module is played and stored by adopting a mobile phone terminal.

The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.