阅读说明：本技术 利用大数据存储的双模式清洁方法 (Dual mode cleaning method utilizing large data storage ) 是由 祝爱莲 于 2020-03-18 设计创作，主要内容包括：本发明涉及一种利用大数据存储的双模式清洁方法,所述方法包括使用利用大数据存储的双模式清洁平台以基于高铁车头玻璃的视觉检测结果执行双模式清洁机制的选择操作。(The present invention relates to a dual mode cleaning method utilizing big data storage, the method comprising using a dual mode cleaning platform utilizing big data storage to perform a selection operation of a dual mode cleaning mechanism based on a visual detection result of a head glass of a high-speed railway.)

1. A dual mode cleaning method utilizing big data storage, the method comprising using a dual mode cleaning platform utilizing big data storage to perform a selection operation of a dual mode cleaning mechanism based on a visual detection result of a head glass of a high-speed railway, the dual mode cleaning platform utilizing big data storage comprising:

the fog spraying mechanism is arranged below the high-speed rail head glass and used for starting fog spraying operation on the high-speed rail head glass when receiving a first trigger command;

in the fog spraying mechanism, in the fog spraying operation of the high-speed rail head glass, the fog spraying power is in direct proportion to the current running speed of the high-speed rail.

2. The method of claim 1, wherein:

and the fog spraying mechanism is also used for stopping carrying out fog spraying operation on the high-speed rail head glass when receiving a second trigger command.

3. The method of claim 2, wherein the platform further comprises:

the liquid injection mechanism is arranged on the left side of the mist injection mechanism and used for starting injection operation of glass cleaning liquid of the high-speed rail head glass when receiving a second trigger command;

in the liquid injection mechanism, in the injection operation of the glass cleaning liquid of the high-speed rail head glass, the power of the glass cleaning liquid injection is in direct proportion to the current running speed of the high-speed rail;

the liquid spraying mechanism is further used for stopping spraying operation of glass cleaning liquid to the high-speed rail head glass when receiving a first trigger command;

the big data storage network element is respectively connected with the fog spraying mechanism and the liquid spraying mechanism through a network and is used for storing the mapping relation between the fog spraying power and the current running speed of the high-speed rail and the mapping relation between the glass cleaning liquid spraying power and the current running speed of the high-speed rail;

the visual analysis equipment is used for extracting a corresponding glass imaging pattern from an imaging image of the environment where the high-speed rail head glass is located based on the geometric shape of the high-speed rail head glass, and determining to send a first trigger command or a second trigger command based on the image which is shot when the high-speed rail head glass leaves a factory and only comprises the high-speed rail head glass and the difference between the glass imaging patterns;

wherein, the step of deciding to send out the first trigger command or the second trigger command based on the image which is shot when the high-speed rail head glass leaves the factory and only comprises the high-speed rail head glass and the difference size between the glass imaging patterns comprises the following steps: taking an image which is shot when the high-speed rail head glass leaves a factory and only comprises the high-speed rail head glass as a first image, and taking the glass imaging pattern as a second image;

wherein, the determining to send out the first trigger command or the second trigger command based on the image shot when the high-speed rail head glass leaves the factory and only including the high-speed rail head glass and the difference size between the glass imaging patterns further comprises: performing difference processing and difference absolute value processing on pixel values of pixel points at the same position in the first image and the second image to obtain pixel difference values of corresponding positions, when the mean value of the pixel difference values respectively corresponding to the positions is larger than a first numerical threshold and smaller than a second numerical threshold, sending a first trigger command, and when the mean value of the pixel difference values respectively corresponding to the positions is larger than or equal to the second numerical threshold, sending a second trigger command;

the visual analysis equipment is respectively connected with the mist spraying mechanism and the liquid spraying mechanism and is used for sending the first trigger command or the second trigger command to the mist spraying mechanism and the liquid spraying mechanism simultaneously.

4. The method of claim 3, wherein the platform further comprises:

and the speed detection equipment is arranged in a control console of the head of the high-speed rail and is used for detecting and outputting the current running speed of the high-speed rail in real time.

5. The method of claim 4, wherein the platform further comprises:

the wiper driving mechanism is respectively connected with the fog spraying mechanism and the liquid spraying mechanism and is used for driving the wiper to realize the cleaning operation of the head glass of the high-speed rail when the fog spraying mechanism or the liquid spraying mechanism is detected to be started;

wherein the frequency of the wiper driving mechanism driving the wiper to perform cleaning operation on the head glass of the high-speed rail is inversely proportional to the current running speed of the high-speed rail.

6. The method of claim 5, wherein the platform further comprises:

the first storage box body is arranged below the head glass of the high-speed rail and used for providing liquid for generating mist for the mist spraying mechanism.

7. The method of claim 6, wherein the platform further comprises:

and the second storage box body is arranged below the head glass of the high-speed rail and used for providing glass cleaning liquid for the liquid spraying mechanism.

8. The method of claim 7, wherein:

the visual analysis equipment is connected with the IIC control bus and used for receiving various control instructions sent by the IIC control bus;

the visual analysis equipment is also connected with a clock generator and used for receiving a timing signal customized by the clock generator for the visual analysis equipment.

9. The method of claim 8, wherein:

and the big data storage network element is also used for storing the mapping relation between the frequency of the wiper executing the cleaning operation on the head glass of the high-speed rail and the current running speed of the high-speed rail.