CN112053418A - Hydroelectric engineering monitoring data drawing system and method - Google Patents

Abstract

The application discloses hydroelectric engineering monitoring data drawing system and method, include: the system comprises a data acquisition module, a safety monitoring data storage module, a visual scene object editing module and a visual scene graph display module, wherein the data acquisition module is connected with the safety monitoring data storage module; the safety monitoring data storage module is electrically connected with the visual scene object editing module; the visual scene object editing module is electrically connected with the visual scene graph display module. The rapid drawing of process lines, a maximum graph, a distribution graph or a vector graph of the hydropower project monitoring points is realized, and the safety monitoring graph analysis work efficiency and the management level are improved.

Description

Hydroelectric engineering monitoring data drawing system and method

Technical Field

The invention relates to a hydropower engineering monitoring data drawing system and method, and belongs to the technical field of hydropower engineering.

Background

In recent years, hydropower develops rapidly in China, numerous high dam warehouses are newly built, such as a bay hydropower station, a Wudongde hydropower station, a white crane beach hydropower station and other dam projects, numerous safety monitoring instruments are distributed in engineering buildings for monitoring the safety performance of the relevant buildings of the engineering, massive safety monitoring data are involved, and in the analysis of hydropower engineering safety data, the problem of how to effectively and rapidly perform graphical analysis on safety monitoring results is a considerable research.

Most of traditional hydropower engineering safety data analysis manages and inquires data through Excel documents, whether related monitoring points and data are searched or data graph analysis is completed through manual operation, particularly complex data graphs such as a maximum graph, a distribution graph or a vector graph are completed through manual drawing of operators in CAD software.

However, when a large amount of data is faced, the safety monitoring data is searched manually, and the graph is drawn manually, so that time and labor are wasted, the obtained result is easy to generate errors, and the user experience is poor. In the face of massive safety monitoring data, the traditional safety monitoring data analysis mode cannot meet the use and development requirements, and a safety monitoring result graph analysis system capable of improving the working efficiency needs to be researched.

Disclosure of Invention

The application provides a hydroelectric engineering monitoring data drawing system and method for solving the problems that in the prior art, hydroelectric engineering safety monitoring data is large in data volume, and when the data is drawn into a monitoring point process line, a maximum graph, a distribution graph or a vector diagram, the efficiency is low, the data is easy to mistake, the data too depends on the experience of an operator, the user experience is poor, and the workload is too large.

The application provides a hydropower engineering monitoring data drawing system,

the method comprises the following steps: a data acquisition module, a safety monitoring data storage module, a visual scene object editing module and a visual scene graph display module,

the data acquisition module is used for acquiring safety monitoring data of a region to be monitored in the hydroelectric engineering and is connected with the safety monitoring data storage module;

the safety monitoring data storage module is used for storing data to construct a safety monitoring database and is electrically connected with the visual scene object editing module;

the visual scene object editing module is used for adding information of opposite monitoring sections, monitoring point objects and character objects on the background picture according to the actual situation of an engineering field after the background picture is loaded, adding instruments for obtaining data of the safety monitoring results at the monitoring points of the background picture according to the instruments for obtaining the data of the safety monitoring results, numbering and storing the monitoring points of the instruments arranged in the background picture in sequence, and electrically connecting the visual scene picture display module;

and the visual scene graph display module is used for determining the monitoring date and drawing the process line query, the maximum graph, the distribution graph or the vector graph of the monitoring points of the data corresponding to the monitoring date.

Preferably, the method comprises the following steps: the visual scene graph display module is electrically connected with the display; the display is electrically connected with the visual scene object editing module.

Preferably, the visual scene object editing module comprises: the background map loading module is used for loading the engineering field map or the design map as a background map;

the information adding module is used for adding information of the opposite side of the monitoring section, the monitoring point object and the character object on the background picture according to the actual engineering site;

the instrument association module is used for adding an instrument for acquiring the data of the point at the monitoring point of the background image according to the instrument for acquiring the data of the safety monitoring result;

the monitoring point numbering module is used for numbering and storing the monitoring points of each instrument set in the background picture in sequence;

the background picture loading module is electrically connected with the information adding module;

the information adding module is electrically connected with the instrument correlation module;

the instrument correlation module is electrically connected with the monitoring point numbering module.

Preferably, the background map loading module is electrically connected with the safety monitoring data storage module.

Preferably, the visual scene graph presentation module comprises: the monitoring date selection module is used for appointing a monitoring date;

the data reading module is used for reading the safety monitoring data of the current day according to the determined monitoring date;

the drawing type selection module is used for determining the type of a drawing analysis curve;

the drawing module is used for drawing monitoring point process line inquiry, a maximum value graph, a distribution graph or a vector graph,

the monitoring date selection module is electrically connected with the data reading module;

the monitoring date selection module is electrically connected with the drawing type selection module;

the drawing type selection module is electrically connected with the drawing module.

Preferably, the data reading module is electrically connected with the safety monitoring data storage module.

Preferably, the drawing module comprises: the monitoring point process line drawing module is used for drawing monitoring point process line query;

the maximum value graph drawing module is used for drawing a maximum value graph;

the distribution diagram drawing module is used for drawing a distribution diagram;

the vector diagram drawing module is used for drawing a vector diagram;

the drawing type selection module is respectively and electrically connected with the monitoring point process line drawing module, the maximum value graph drawing module, the distribution graph drawing module and the vector diagram drawing module.

Another aspect of the present application further provides a method for plotting monitoring data of hydroelectric engineering, comprising the following steps:

step S100: collecting safety monitoring data of a region to be monitored in the hydropower engineering;

step S200: storing data to construct a safety monitoring database;

step S300: after loading the background picture, adding information of the opposite side of the monitoring section, the monitoring point objects and the character objects on the background picture according to the actual situation of the engineering site, adding an instrument for obtaining the data of the safety monitoring result at the monitoring point of the background picture according to the instrument for obtaining the data of the safety monitoring result, and numbering and storing the monitoring points of each instrument set in the background picture in sequence;

step S400: and determining a monitoring date, and drawing a process line query, a maximum graph, a distribution graph or a vector graph of monitoring points of data corresponding to the monitoring date.

Preferably, step S300 includes:

step S301: loading an engineering field map or a design map as a background map;

step S302: adding information of opposite monitoring sections, monitoring point objects and character objects on the background picture according to the actual engineering site;

step S303: adding an instrument for obtaining the data of the point at the monitoring point of the background image according to the instrument for obtaining the data of the safety monitoring result;

step S304: and numbering and storing monitoring points of each instrument set in the background picture in sequence.

Preferably, step S400 includes:

step S401: appointing a monitoring date;

step S402: reading safety monitoring data of the current day according to the determined monitoring date;

step S403: and drawing a process line query, a maximum graph, a distribution graph or a vector graph of the monitoring points.

The beneficial effects that this application can produce include:

1) the utility model provides a hydroelectric engineering monitoring data drawing system has realized the quick drawing of hydroelectric engineering monitoring point process line, most value picture, distribution diagram or vector diagram, improves safety monitoring graphical analysis work efficiency and management level.

2) The utility model provides a hydroelectric engineering monitoring data drawing system realizes that objects such as safety monitoring section, monitoring point self-defined setting and monitoring point process line, most picture, distribution map or vector diagram on the background picture draw in real time among the hydroelectric engineering, satisfies hydroelectric engineering safety monitoring data figure analysis needs, and lifting efficiency 80%.

Drawings

FIG. 1 is a schematic diagram of a module connection of a hydroelectric engineering monitoring data mapping system provided by the present application;

FIG. 2 is a schematic view of another connection mode of a hydroelectric engineering monitoring data mapping system module provided by the present application;

fig. 3 is a schematic structural diagram of a visualized scene object editing module provided in the present application;

FIG. 4 is a schematic structural diagram of a visual scene graph display module provided in the present application;

FIG. 5 is a screenshot of a monitor point object attribute information display in an embodiment of the present application;

FIG. 6 is a screenshot of a textual object attribute information display in an embodiment of the present application;

FIG. 7 is a schematic view of a process line of a monitoring point object in the embodiment of the present application;

FIG. 8 is a plot of the maxima and minima plotted in an example of the present application;

FIG. 9 is a distribution chart as plotted in the examples of the present application;

fig. 10 is a layout and vector diagram of monitoring points for surface deformation of a certain sliding mass in the embodiment of the present application, wherein a) is a schematic diagram of the layout positions of the monitoring points; b) is a vector diagram;

fig. 11 is a schematic flow chart of a hydroelectric engineering monitoring data mapping method provided by the present application.

Illustration of the drawings:

10. a data acquisition module; 20. a safety monitoring data storage module; 30. a visual scene object editing module; 301. a background map loading module; 302. an information adding module; 303. an instrument association module; 304. a monitoring point numbering module; 40. a visual scene graph display module; 401. a data reading module; 402. a monitoring date selection module; 403. a drawing type selection module; 404. a monitoring point process line drawing module; 405. a maximum graph drawing module; 406. a distribution diagram drawing module; 407. a vector diagram drawing module; 50. a display.

Detailed Description

The present application will be described in detail with reference to examples, but the present application is not limited to these examples.

Referring to fig. 1, the utility model provides a hydroelectric engineering monitoring data mapping system includes:

the data acquisition module 10 is used for acquiring data of a region to be monitored in the hydroelectric engineering and is electrically connected with the safety monitoring data storage module 20;

the safety monitoring data storage module 20 is used for storing the data acquired in the data acquisition module 10 and constructing a safety monitoring database; the safety monitoring data storage module 20 is respectively in data connection with the visual scene object editing module 30 and the data acquisition module 10 for data storage and recording; the safety monitoring data storage module 20 also stores information such as an actual background map of the engineering site, a safety monitoring background map, a section object, a monitoring point object, a character object and the like; when the electronic data acquisition device is used, data acquired by the acquisition module can be manually input into the electronic data acquisition device for storage.

The visual scene object editing module 30 is used for adding information of the opposite side of the monitoring section, the monitoring point object and the character object on the background image according to the actual engineering site after loading the background image, and then adding an instrument for obtaining data of safety monitoring results at the monitoring point of the background image according to the instrument for obtaining the data; numbering and storing monitoring points of each instrument set in the background picture in sequence;

the safety monitoring data storage module 20 is electrically connected with the visual scene object editing module 30;

so as to display the position of the data monitoring point on the background picture when the subsequent data is analyzed.

The visual scene graph display module 40 is used for respectively drawing monitoring point process line query, maximum graph drawing, distribution graph drawing and vector diagram drawing according to needs after a monitoring date is selected based on the monitoring section, monitoring point, character and safety monitoring data storage module 20 which is set in visual scene object editing;

the visual scene graph presentation module 40 is electrically connected to the visual scene object editing module 30.

According to the numerical value, the collected actual data can be stored and then edited and marked, the image required by analysis is drawn through the visual scene graph display module 40, manual drawing is not needed, the operation precision of drawing an obtained analysis curve is improved, the user experience is improved, the workload is reduced, and especially when a large amount of data is faced, the analysis work efficiency is improved.

The utility model provides a system is through with data acquisition module 10, safety monitoring data storage module 20, visual scene object editor module 30, visual scene figure display module 40 connects gradually, the realization is to the safety monitoring background picture, the section object, the monitoring point object, word object and safety monitoring achievement data, realize among the water and electricity engineering safety monitoring section, the self-defined setting and the monitoring point process line of objects such as monitoring point on the background picture, the most important picture, distribution diagram or vector diagram are drawn in real time, satisfy water and electricity engineering safety monitoring data figure analysis demand, raise the efficiency 80%.

In the data acquisition module 10, the data acquired by the used instrument can be examination basis data and safety monitoring compilation result data.

The monitoring background picture can be an engineering field background picture, a design drawing picture and the like; the section object is a monitoring section arranged on the safety monitoring background image and is represented by a straight line; the monitoring point objects are safety monitoring points on a monitoring section of the background image and are represented by icons, the icons of different types of monitoring instruments are different, the icons can move interactively on the background image, and attribute information including monitoring point numbers, icon types and the like can be set; the character object is used for describing monitoring point number information description of the monitoring point object, can be moved interactively on the background picture, and can be provided with attribute information including character content, character size, color and the like.

The monitoring point process line query is to draw the monitoring point process line associated with the object by selecting the monitoring point object on the background graph;

the most value graph drawing is to inquire and draw the monitoring data related to the monitoring point object according to preset inquiry conditions, for example, only draw a measured value that the anchor cable design value is greater than 2000, the character color is white, the character size is 16, and the character background is blue;

the distribution diagram drawing is a graph for drawing a multipoint type instrument and is drawn according to different depth measurement values of the multipoint instrument, for example, component measurement values of different depth measurement values of a certain multipoint displacement meter are represented by lengths of straight lines perpendicular to a hole direction, the top points of the straight lines and the two ends of the hole direction straight lines are connected by the straight lines, and colors are filled;

the vector diagram is drawn mainly aiming at the monitoring result value of the surface deformation monitoring point of the side slope or the landslide body, the horizontal resultant displacement is represented by a straight line and an arrow, the length of the straight line represents the size of the horizontal resultant displacement, the arrow represents the direction of the horizontal resultant displacement, the vertical displacement is represented by a circle, and the radius of the circle represents the size of the vertical displacement.

The system provided by the invention edits and constructs a safety monitoring background picture, a section object, a monitoring point object and a character object through a visual scene, stores the pixel position information of the section object, the monitoring point object and the character object on the background picture, simultaneously associates the monitoring point numbers with the monitoring point object, searches the corresponding safety monitoring data result in the safety monitoring data storage module 20 by using the monitoring point associated with the monitoring point object in the visual display module, selects the monitoring date, and draws a monitoring point process line, a maximum value picture, a distribution map or a vector map in real time, thereby providing a quick and effective way for the graphic analysis and application of the safety monitoring result data of the hydropower engineering.

Referring to fig. 2, preferably, it comprises: the display 50, the visual scene graph display module 40 is electrically connected with the display 50; the display 50 is electrically connected to the visual scene object editing module 30. According to the arrangement, the display background map can be implemented on the display 50, and the operations of the visual scene graph display module 40 and the visual scene object editing module 30 are facilitated.

Preferably, the data acquisition module 10 is any one of a multi-point displacement meter, a bolt strain gauge, an anchor line dynamometer, and a surface deformation monitoring point. When the monitoring instrument is any one of the monitoring instruments, the instrument is respectively in data transmission connection with the safety monitoring data storage module 20.

Referring to fig. 3, preferably, the visualization scene object editing module 30 includes:

a background map loading module 301, configured to load an engineering field map or a design map as a background map;

the information adding module 302 is used for actually adding information of the opposite side of the monitoring section, the monitoring point object and the character object on the background picture according to the engineering site;

the instrument association module 303 is configured to add an instrument for obtaining the point data at the monitoring point of the background map according to the instrument for obtaining the safety monitoring result data;

a monitoring point numbering module 304, configured to number and store monitoring points of each instrument set in the background image in sequence;

the background map loading module 301 is electrically connected with the information adding module 302; the information adding module 302 is electrically connected with the instrument association module 303; the instrument association module 303 is electrically connected to the monitoring point numbering module 304.

The connection can thus be made modular for the above-mentioned functions.

Referring to fig. 4, preferably, the visualization scene graph presentation module 40 includes:

a monitoring date selection module 402 for specifying a monitoring date;

a data reading module 401, configured to read the current-day safety monitoring data according to the determined monitoring date; a drawing type selection module 403, configured to select a type of a curve to be drawn;

the drawing module is used for drawing various curves;

the monitoring date selection module 402 is electrically connected with the data reading module 401; the monitoring date selection module 402 is electrically connected with the drawing type selection module 403; the drawing type selection module 403 is electrically connected to the drawing module.

After the sub-modules are connected according to the method, the data acquired at different monitoring times can be respectively drawn to process line query, a maximum graph, a distribution graph or a vector graph of the monitoring points.

Preferably, the data reading module 401 is electrically connected with the security monitoring data storage module 20.

Preferably, the background map loading module 301 is electrically connected to the safety monitoring data storage module 20.

Preferably, the drawing module comprises: a monitoring point process line drawing module 404, configured to draw a monitoring point process line query curve;

a maximum graph drawing module 405, configured to draw a maximum graph;

a profile drawing module 406 for drawing a profile;

a vector diagram drawing module 407, configured to draw a vector diagram;

the drawing type selection module 403 is electrically connected to the monitoring point process line drawing module 404, the maximum graph drawing module 405, the distribution graph drawing module 406, and the vector diagram drawing module 407, respectively.

Referring to fig. 11, the present application provides a method for plotting monitoring data of a hydroelectric engineering, comprising the following steps:

step S100: collecting safety monitoring data of a region to be monitored in the hydropower engineering;

the method comprises the steps of collecting various types of safety monitoring data related to hydroelectric engineering, wherein the instrument types comprise a multipoint displacement meter, an anchor rod stress meter, an anchor cable dynamometer, surface deformation monitoring points and the like, and various instrument data comprise examination evidence basic data and safety monitoring compilation result data.

Step S200: storing data to construct a safety monitoring database; for data storage and recording;

step S300: after loading the background picture, adding information of the opposite side of the monitoring section, the monitoring point objects and the character objects on the background picture according to the actual situation of the engineering site, adding an instrument for obtaining the data of the safety monitoring result at the monitoring point of the background picture according to the instrument for obtaining the data of the safety monitoring result, and numbering and storing the monitoring points of each instrument set in the background picture in sequence; the used monitoring background picture can be a background picture of an engineering field, a design drawing picture and the like;

step S400: and determining a monitoring date, and drawing a process line query, a maximum graph, a distribution graph or a vector graph of monitoring points of data corresponding to the monitoring date.

According to the method, the obtained data can be comprehensively analyzed, the one-to-one correspondence between the monitoring positions and the monitoring data is realized on the Beijing image, the accuracy of the post-drawing result is improved, the workload is reduced, and the data can be processed only on the background image.

Preferably, step S300 includes:

step S301: loading an engineering field map or a design map as a background map;

step S302: adding information of opposite monitoring sections, monitoring point objects and character objects on the background picture according to the actual engineering site;

step S303: adding an instrument for obtaining the data of the point at the monitoring point of the background image according to the instrument for obtaining the data of the safety monitoring result;

step S304: and numbering and storing monitoring points of each instrument set in the background picture in sequence.

According to the steps, the data and the monitoring points can be corresponding to each other on the background graph, and the required data is provided for the subsequent drawing of the analysis curve.

Preferably, step S400 includes:

step S401: appointing a monitoring date;

step S402: reading safety monitoring data of the current day according to the determined monitoring date;

step S403: and drawing a process line query, a maximum graph, a distribution graph or a vector graph of the monitoring points.

Drawing the required drawings according to the requirements of various existing analysis curve graphs respectively according to the steps. By adopting the step, the detection results under different monitoring time can be respectively drawn according to the data, and the use and the analysis are convenient.

In a specific embodiment, the operation process of the hydropower engineering safety monitoring result graph analysis system comprises the following steps:

step S100: constructing a safety monitoring data storage module 20; storing various types of safety monitoring data related to the hydropower engineering, wherein the various instrument data comprise examination evidence basic data and safety monitoring compilation result data;

step S200: in the editing of the visual scene object, firstly, a safety monitoring background picture is added, and on the basis of the safety monitoring background picture, a monitoring point object and a character object which are opposite to a monitoring section and are actually added on the visual scene object according to an engineering field are added.

Step S300: based on a monitoring section, monitoring points, characters and a safety monitoring result database which are set in visual scene object editing, selecting a monitoring date, clicking to draw, and drawing a process line, a most valued graph and a distribution graph in real time.

Taking a certain landslide surface deformation monitoring point as an embodiment, after data obtained by each monitoring point is processed by the system provided by the application, a monitoring point object process line, a maximum graph, a distribution graph, a monitoring point arrangement and a vector graph are respectively drawn, the operation process is shown in FIG. 5, in a monitoring point object attribute information graph, instrument types needing to be added, such as a multi-point displacement meter, an anchor cable dynamometer and the like, are selected in a system toolbar, then, a monitoring point object can be placed by clicking on a background graph, the position of the object can be dragged to a correct position from top to bottom and from left to right through a mouse, then, a measuring point number is set in right-side attribute information of FIG. 6 and stored, and at the moment, the monitoring point object is associated to a safety monitoring data storage module 20. The steps of monitoring the addition of the section object and the character object are similar to the steps;

fig. 7 is a process line of monitoring points DPycx0+208-2, fig. 8 is a deformation maximum distribution diagram of each part of a main plant on the right bank, fig. 9 is a deformation distribution diagram of a multipoint displacement meter of a monitoring section of a main cavern in an underground cavern, and fig. 10 is a vector diagram of deformation distribution of surface deformation monitoring points of a certain landslide body in hydroelectric engineering.

As can be seen from a) to b) of FIG. 10, the obtained result is visual and accurate, basically has no deviation, has small processing workload, and can realize the drawn curve on the background map directly, thereby improving the detection accuracy.

Reference throughout this specification to "one embodiment," "another embodiment," "an embodiment," "a preferred embodiment," or the like, means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment described generally in this application. The appearances of the same phrase in various places in the specification are not necessarily all referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with any embodiment, it is submitted that it is within the scope of the disclosure to effect such feature, structure, or characteristic in connection with other embodiments.

Although the present application has been described herein with reference to a number of illustrative embodiments thereof, it should be understood that numerous other modifications and embodiments can be devised by those skilled in the art that will fall within the spirit and scope of the principles of this disclosure. More specifically, various variations and modifications are possible in the component parts and/or arrangements of the subject combination arrangement within the scope of the disclosure and claims of this application. In addition to variations and modifications in the component parts and/or arrangements, other uses will also be apparent to those skilled in the art.

Claims (10)

1. The utility model provides a water electrical engineering monitoring data graphic system which characterized in that includes: a data acquisition module (10), a safety monitoring data storage module (20), a visual scene object editing module (30) and a visual scene graph display module (40),

the data acquisition module (10) is used for acquiring safety monitoring data of a region to be monitored in the hydropower engineering and is connected with the safety monitoring data storage module (20);

the safety monitoring data storage module (20) is used for storing data to construct a safety monitoring database and is electrically connected with the visual scene object editing module (30);

the visual scene object editing module (30) is used for adding information of opposite monitoring sections, monitoring point objects and character objects on the background picture according to the actual situation of the engineering site after loading the background picture, adding instruments for obtaining the data of the point at the monitoring points of the background picture according to the instruments for obtaining the data of the safety monitoring results, numbering and storing the monitoring points of the instruments arranged in the background picture in sequence, and electrically connecting the visual scene picture displaying module (40);

and the visual scene graph display module (40) is used for determining a monitoring date and drawing a monitoring point process line query, a maximum graph, a distribution graph or a vector graph of data corresponding to the monitoring date.

2. A hydroelectric engineering monitoring data mapping system according to claim 1 comprising: the display (50), the visual scene graph display module (40) is electrically connected with the display (50); the display (50) is electrically connected to a visual scene object editing module (30).

3. A hydroelectric engineering monitoring data mapping system according to claim 1 wherein the visual scene object editing module (30) comprises: the background map loading module (301) loads an engineering field map or a design map as a background map;

the information adding module (302) is used for actually adding information of the opposite side of the monitoring section, the monitoring point object and the character object on the background picture according to the engineering site;

the instrument association module (303) is used for adding an instrument for acquiring the data of the point at the monitoring point of the background image according to the instrument for acquiring the data of the safety monitoring result;

the monitoring point numbering module (304) is used for numbering and storing the monitoring points of each instrument set in the background picture in sequence;

the background image loading module (301) is electrically connected with the information adding module (302);

the information adding module (302) is electrically connected with the instrument association module (303);

the instrument association module (303) is electrically connected with the monitoring point numbering module (304).

4. A hydroelectric engineering monitoring data mapping system according to claim 3 in which the background map loading module (301) is electrically connected to the safety monitoring data storage module (20).

5. A hydroelectric engineering monitoring data mapping system according to claim 1, wherein the visualization scenario graphic display module (40) comprises: a monitoring date selection module (402) for specifying a monitoring date;

the data reading module (401) reads the safety monitoring data of the current day according to the determined monitoring date;

a drawing type selection module (403) for determining the type of the drawing analysis curve;

the drawing module is used for drawing monitoring point process line inquiry, a maximum value graph, a distribution graph or a vector graph,

the monitoring date selection module (402) is electrically connected with the data reading module (401);

the monitoring date selection module (402) is electrically connected with the drawing type selection module (403);

the drawing type selection module (403) is electrically connected with the drawing module.

6. The mapping system for hydroelectric engineering data according to claim 5, wherein the data reading module (401) is electrically connected to the safety monitoring data storage module (10).

7. A hydroelectric engineering monitoring data mapping system according to claim 5 in which the mapping module comprises: the monitoring point process line drawing module (404) is used for drawing monitoring point process line query;

a maximum value drawing module (405) for drawing a maximum value drawing;

a profile rendering module (406) for rendering a profile;

a vector diagram drawing module (407) for drawing a vector diagram;

the drawing type selection module (403) is respectively and electrically connected with the monitoring point process line drawing module (404), the maximum value drawing module block (405), the distribution diagram drawing module (406) and the vector diagram drawing module (407).

8. A hydroelectric engineering monitoring data drawing method is characterized by comprising the following steps:

step S100: collecting safety monitoring data of a region to be monitored in the hydropower engineering;

step S200: storing data to construct a safety monitoring database;

step S300: after loading the background picture, adding information of the opposite side of the monitoring section, the monitoring point objects and the character objects on the background picture according to the actual situation of the engineering site, adding an instrument for obtaining the data of the safety monitoring result at the monitoring point of the background picture according to the instrument for obtaining the data of the safety monitoring result, and numbering and storing the monitoring points of each instrument set in the background picture in sequence;

step S400: and determining a monitoring date, and drawing a process line query, a maximum graph, a distribution graph or a vector graph of monitoring points of data corresponding to the monitoring date.

9. A method for plotting monitoring data of a hydroelectric project according to claim 1, wherein step S300 comprises:

step S301: loading an engineering field map or a design map as a background map;

step S302: adding information of opposite monitoring sections, monitoring point objects and character objects on the background picture according to the actual engineering site;

step S303: adding an instrument for obtaining the data of the point at the monitoring point of the background image according to the instrument for obtaining the data of the safety monitoring result;

step S304: and numbering and storing monitoring points of each instrument set in the background picture in sequence.

10. A method for plotting hydroelectric engineering monitoring data according to claim 1, wherein step S400 comprises:

step S401: appointing a monitoring date;

step S402: reading safety monitoring data of the current day according to the determined monitoring date;

step S403: and drawing a process line query, a maximum graph, a distribution graph or a vector graph of the monitoring points.

Images