CN108289207B - Anti-seepage monitoring system based on terminal and monitoring control method - Google Patents

Abstract

The invention discloses a terminal-based anti-seepage monitoring system and a monitoring control method, and belongs to the field of anti-seepage engineering. The invention provides a terminal-based anti-seepage monitoring system and a monitoring control method, aiming at the problems that when anti-seepage equipment is put into a use environment, the on-site environment cannot be effectively monitored and managed, and a large amount of manpower and material resources are consumed. Acquiring a field image through image monitoring equipment; the dehumidification seepage-proofing device is used for collecting field environment parameters; the main control equipment receives the information of the image monitoring equipment and the dehumidification anti-seepage device, processes the received information of the image monitoring equipment and the dehumidification anti-seepage device, and returns a terminal control signal to the image monitoring equipment and the dehumidification anti-seepage device; the terminal is correspondingly controlled, visualization of data and light management can be achieved, an expected solution is formulated to reduce working difficulty, working environment range is expanded, and the mobile phone mobile terminal is convenient to replace and carry and has excellent characteristics of remote terminal visualization operation and the like.

Description

Anti-seepage monitoring system based on terminal and monitoring control method

Technical Field

The invention relates to the field of seepage-proofing engineering, in particular to a seepage-proofing monitoring system and a monitoring control method based on a terminal.

Background

The problems of leakage and harmfulness of the existing house buildings are more and more, the outer wall of the building is also the key point of house water resistance, the using effect and the service life of the building can be directly influenced due to the good and bad anti-leakage quality of the wall, so that great troubles are brought to the work of property management, professional maintenance and the like, huge physical and mental losses are brought to owners and residents, and the outer wall serving as a coat of the building can withstand the test of wind blowing, sunshine and rainwater scouring under a specific natural environment. The anti-seepage method can be used for anti-seepage through an anti-seepage device in the aspect of construction, the anti-seepage device can generate special waveform current, the current forms an electromagnetic field through an anode embedded in the concrete structure and a cathode embedded outside the concrete structure, the magnetic field attracts water molecules to the outer side of the structure, and the water molecules cannot enter the structure (concrete or masonry) any more as long as the electromagnetic field is uninterrupted, so that the structure is in a relatively dry state for a long time.

When this kind puts into the operational environment with anti-seepage equipment, can not carry out effectual control and management to the site environment, need consume a large amount of manpower and materials, the concrete expression is: the measurement of the on-site anti-seepage equipment has a sudden problem, a user cannot solve the problem, a professional is required to maintain the anti-seepage equipment, a large amount of manpower, material resources and time are occupied in the whole process, the anti-seepage equipment cannot normally operate, and meanwhile, the experience of a user is seriously influenced.

To sum up, how to effectively solve the problem in the prior art, realize the visualization of data and the lightweight of management, utilize manual on-the-spot solution, alleviate the work degree of difficulty, enlarge operational environment scope, realize that the convenient change of cell-phone mobile terminal and carrying, good characteristics such as the visual operation of remote terminal are very important. In the prior art, no corresponding scheme is provided for effectively monitoring and managing an anti-seepage monitoring system.

Disclosure of Invention

1. Technical problem to be solved

The invention provides a terminal-based anti-seepage monitoring system and a monitoring control method, aiming at the problems that when anti-seepage equipment is put into a use environment, the on-site environment cannot be effectively monitored and managed, and a large amount of manpower and material resources are consumed. The mobile phone mobile terminal can realize the visualization of data and the light weight of management, formulate an expected solution to reduce the work difficulty, enlarge the working environment range, and realize the excellent characteristics of convenient replacement and carrying of the mobile phone mobile terminal, the visualization operation of a remote terminal and the like.

2. Technical scheme

The purpose of the invention is realized by the following technical scheme.

A terminal-based anti-seepage monitoring system comprises,

the image monitoring equipment is used for acquiring field images;

the dehumidification seepage-proofing device is used for collecting field environment parameters;

the main control equipment receives the information of the image monitoring equipment and the dehumidification anti-seepage device, processes the received information of the image monitoring equipment and the dehumidification anti-seepage device, and returns a terminal control signal to the image monitoring equipment and the dehumidification anti-seepage device;

and the terminal receives the information sent by the main control equipment and returns the control information to the main control equipment.

Furthermore, the image monitoring equipment comprises a plurality of cameras, and the cameras are arranged on an engineering site.

Furthermore, the dehumidification anti-seepage device comprises a first collecting device fixedly arranged on the wall of the space to be detected and a second collecting device longitudinally moving along the wall of the space to be detected. A first acquisition back-up device may also be included that may be used to replace the first acquisition device.

Furthermore, the second collecting device which moves longitudinally along the wall of the space to be detected is arranged on the moving carrier, the rail is arranged on the wall of the space to be detected, and the moving carrier moves on the rail.

Furthermore, the terminal is a mobile terminal or a background computer system.

A monitoring control method of an anti-seepage monitoring system based on a terminal comprises the following steps:

(1) setting a normal parameter range and a standard video image through a terminal, and sending information to a main control device;

(2) the main control equipment acquires a real-time video image of a site through image monitoring equipment arranged on the site, and acquires a real-time environment parameter value of the site through a dehumidification anti-seepage device which is arranged on the site and has the functions of measurement and transmission;

(3) the main control equipment compares the real-time environment parameter value with a set parameter range and judges whether the environment state is abnormal or not;

if the real-time environment parameter value falls into the set parameter range, judging the real-time environment parameter value to be normal; sending information to a terminal, and displaying a normal prompt on the terminal; if the real-time environment parameter value is out of the set parameter range, sending information to the terminal, and displaying abnormal prompts on the terminal;

comparing the real-time video image with the set video image, if the real-time video image is consistent with the set video image, sending information to the terminal, and displaying a normal prompt on the terminal; if the two are inconsistent, sending information to the terminal, and displaying abnormal prompts on the terminal;

(4) according to the abnormal real-time environment parameter values displayed by the terminal, the terminal judges the field problems, provides a solution, selects the terminal solution to carry out the step (5), selects a manual solution and enters the step (6);

(5) according to the solution, the terminal generates a corresponding signal and sends the signal to the main control equipment, and the main control equipment controls the image monitoring equipment and the dehumidification seepage-proofing device to set so as to solve the problem;

(6) and prompting manual field solution according to the solution.

Furthermore, the abnormal real-time environment parameter value and/or the abnormal real-time video image displayed by the terminal in the step (3) are used for judging the site problems, the site state is as follows,

(a) if the real-time field environment parameter value is continuously 0, the terminal displays normal video;

(b) if the real-time field environment parameter value jumps in a large range, the terminal displays normal video;

(c) if the real-time field environment parameter value jumps in a large range, and the terminal displays abnormal video;

(d) and if the real-time field environment parameter value is continuously a constant value, the terminal displays normal video.

Furthermore, the real-time environment parameter value is displayed on the terminal device in a line graph form.

Further, steps (5) and (6) further include a process of uploading the obtained field problem and the provided corresponding solution to the cloud server. The system can also comprise a cloud server, corresponding problems are uploaded, a more comprehensive database of the problems and schemes is obtained, and a better solution is obtained.

Furthermore, the main control device in step (3) calculates the real-time environment parameter value collected by the dehumidification seepage-proofing device to obtain a real-time monitoring value, and the real-time environment parameter value is compared with the set parameter range.

The specific method for acquiring data is as follows: (A) the method comprises the steps that a main control device obtains first data, wherein the first data are obtained by processing humidity acquired by a first acquisition device and/or a first acquisition standby device;

(A1) the main control equipment transmits a data acquisition instruction to each first acquisition equipment, and triggers each first acquisition equipment to acquire and process data to obtain first data;

the main control equipment transmits a data sending instruction to each first acquisition equipment, and triggers each first acquisition equipment to send the first data;

(A2) the main control device judges whether the first data is received, if so, the step (A3) is carried out; if not, go to step (A4);

(A3) if the main control equipment judges whether the first data is accurate, if so, storing the first data for later use, and entering the step (3); if not, entering the step (A4);

(A4) the main control equipment transmits a data acquisition instruction to the first acquisition standby equipment, and triggers the first acquisition standby equipment to acquire and process data to obtain first data;

the main control equipment transmits a data sending instruction to the first acquisition standby equipment and triggers the first acquisition standby equipment to send the first data;

(A5) after the step (a4), the process returns to the step (a2) to make a judgment.

The step of processing the data by the first acquisition equipment and/or the first acquisition standby equipment to obtain the first data is as follows: the following calculation was used:

wherein Hum_{Fixing device}For fixed acquisition Point integrated humidity, the first data is Hum_{Fixing device}N is a natural number and represents the number of fixed acquisition points, i represents the ith fixed acquisition point, Nodei represents the humidity acquired by a sensor on first acquisition equipment and/or first acquisition standby equipment on the ith fixed acquisition point, and Hum_{Null 0}The expected value of the air humidity of the space to be measured is obtained.

(B) The main control equipment acquires second data, wherein the second data is obtained by processing the humidity acquired by the second acquisition equipment;

(B1) the main control equipment sends a movement control starting instruction to the movement controller to control the second acquisition equipment to move according to a set path;

after the time T is reached, the main control equipment sends a movement control ending instruction to the movement controller to control the second acquisition equipment to stop moving;

(B2) in time T, the main control equipment transmits a data acquisition instruction to the second acquisition equipment according to an interval period T1, and the second acquisition equipment is triggered to acquire and process data to obtain second data;

the main control equipment transmits a data sending instruction to the second acquisition equipment according to an interval period t1, and triggers the second acquisition equipment to send the second data; .

And the main control equipment receives the second data and stores the second data for later use.

The step of the second acquisition device performing data processing to obtain second data is as follows: the following calculation was used:

wherein, Y represents the total number of the positions of a certain movable acquisition point at different heights of the wall surface, j represents the jth position measured by the movable acquisition point, Nodej represents the humidity acquired by a sensor on the second acquisition equipment at the jth position, and NHum_OffsetAcquisition Point for each move relative to Hum_{Null 0}A deviation of (a);

wherein Hum_OffsetFor moving acquisition point relative Hum_{Null 0}K is a natural number and represents the kth mobile acquisition point, M is a natural number and represents the total number of the mobile acquisition points, NHum_OffsetAcquisition Point for each move relative to Hum_{Null 0}Deviation of (1), NHumk_OffsetThe calculation formula is NHum_OffsetThe calculation formula of (2).

Hum_{Moving device}＝Hum_{Null 0}+Hum_Offset；

Wherein Hum_{Moving device}For moving collection points to synthesize humidity, Hum_{Moving device}As second data, Hum_{Null 0}For the expected value of the air humidity of the space to be measured, Hum_OffsetFor moving acquisition point relative Hum_{Null 0}The combined deviation of (2).

(3) And the main control equipment processes the first data and the second data to obtain a monitoring value.

The main control equipment processes the first data and the second data to obtain a monitoring value, and the following calculation is adopted:

Hum_{air (a)}＝Hum_{Null 0}+Hum_{Air bias}；

Wherein Hum_{Air (a)}For the integrated humidity of the air in the space to be measured, Hum_{Air (a)}For monitoring values, Hum_{Air bias}Is the integrated deviation of the integrated humidity of the air in the space to be measured, Hum_{Null 0}The expected value of the air humidity of the space to be measured is obtained;

wherein Hum_OffsetFor moving acquisition points relative to Hum_{Null 0}Integrated deviation of (Hum)_{Deviation from fixation}For fixed acquisition points relative to Hum_{Null 0}The comprehensive deviation of (2);

wherein Hum_{Deviation from fixation}For fixed acquisition points relative to Hum_{Null 0}The comprehensive deviation of the data acquisition system is shown as the following steps, wherein N is a natural number, N represents the number of fixed acquisition points, i represents the ith fixed acquisition point, and Nodei represents the humidity acquired by a first acquisition device on the ith fixed acquisition point and/or a sensor on first acquisition standby equipment;

wherein Hum_OffsetFor moving acquisition points relative to Hum_{Null 0}K is a natural number and represents the kth mobile acquisition point, M is a natural number and represents the total number of the mobile acquisition points, NHum_OffsetAcquisition Point for each move relative to Hum_{Null 0}A deviation of (a);

y represents the total number of the positions of a certain movable acquisition point at different heights of the wall surface, Y is a natural number, j represents the jth position measured by the movable acquisition point, and Nodej represents the humidity acquired by a sensor on the second acquisition equipment at the jth position.

This scheme is through Hum_{Air (a)}The set value and the real-time detection value judge whether the corresponding site has the condition or not and whether the whole system operates normally or not.

3. Advantageous effects

Compared with the prior art, the invention has the advantages that:

(1) the invention adds a terminal and an image monitoring device on the anti-seepage device, wherein the image monitoring device is arranged on a detection site and is used for monitoring the site in real time, the terminal is a user terminal or a background computer system terminal, and the terminal can interact with the anti-seepage device and is used for inputting instructions to the anti-seepage device or displaying environmental parameter values measured by the anti-seepage device and a video image of the site measured by the image monitoring device; the user can remotely observe the anti-seepage condition of the monitored environment through the terminal, problem pre-judgment can be carried out through terminal operation when abnormal real-time environment parameter values displayed by the terminal are displayed, a solution is obtained, instructive problem solution is realized, the defects and defects that a general user cannot operate due to the fact that the general user does not know the problem when being used as an operator, and needs to request help of a professional or operate blindly by the user are overcome, manpower and material resources are saved in the whole process, the user operation is facilitated, the equipment is efficiently used, and convenience is brought to the user and a developer;

(2) in the process of the scheme, if the problem can not be solved through terminal control, a solution is provided for the user to guide the user to carry out on-site problem processing, the processing result is transmitted to the terminal, and examination reference and basis are provided for later maintenance. The anti-seepage equipment engineering management method realizes the visualization of data and the light management, makes an expected solution to reduce the working difficulty and enlarge the working environment range, and the terminal has the excellent characteristics of convenient carrying, visualized operation and the like;

(3) the cloud system acquires corresponding solutions from the database and sends the solutions to the terminal through corresponding problems of the server uploaded to the cloud system, so that the problems are solved better, and timeliness are good;

(4) according to the scheme, the environment monitoring of different positions of the space to be detected is realized by combining the first acquisition equipment and the movable second acquisition equipment, the acquisition of the environment parameters of the whole space to be detected can be realized by adopting less acquisition equipment, and the waste of the acquisition equipment is avoided. By adopting the first acquisition equipment and the second acquisition equipment, comprehensive and accurate data acquisition of the space to be detected by adopting less acquisition equipment is realized, and the system is simple and convenient and can ensure the comprehensive data acquisition, the accuracy and the effectiveness. Meanwhile, the main control equipment is communicated with the first acquisition equipment and the second acquisition equipment, so that the main control equipment can conveniently control the first acquisition equipment and the second acquisition equipment;

(5) according to the scheme, the monitoring value is obtained by processing the first data and the second data after the control equipment acquires the first data which is the comprehensive humidity of the fixed acquisition point and the second data which is the comprehensive humidity of the movable acquisition point, and the real value of the environmental parameter of the space to be measured can be comprehensively and accurately reflected by processing the relevant environmental parameters acquired by the acquisition equipment arranged on the fixed acquisition point and the movable acquisition point, so that the condition of the site environment is better reflected, the error is greatly reduced, the judgment is rapid, and the problem can be solved by accurately selecting a corresponding method.

Drawings

FIG. 1 is a flow chart of the system architecture of the present invention;

FIG. 2 is a flow chart of a monitoring control method of the present invention;

fig. 3 is a flowchart of a process for providing a scenario after the terminal determines.

Detailed Description

The invention is described in detail below with reference to the drawings and specific examples.

Example 1

As shown in fig. 1, a terminal-based anti-seepage monitoring system includes,

the image monitoring equipment is used for acquiring field images; the image monitoring equipment comprises a plurality of cameras, and the cameras are arranged on an engineering site.

The dehumidification seepage-proofing device is used for collecting field environment parameters; the dehumidification anti-seepage device comprises first collection equipment fixedly arranged on the wall of the space to be detected and second collection equipment longitudinally moving along the wall of the space to be detected. A first acquisition back-up device may also be included that may be used to replace the first acquisition device. The second collecting device moving longitudinally along the wall of the space to be detected is arranged on the moving carrier, the rail is arranged on the wall of the space to be detected, and the moving carrier moves on the rail.

The main control equipment receives the information of the image monitoring equipment and the dehumidification anti-seepage device, processes the received information of the image monitoring equipment and the dehumidification anti-seepage device, and returns a terminal control signal to the image monitoring equipment and the dehumidification anti-seepage device;

and the terminal receives the information sent by the main control equipment and returns the control information to the main control equipment. The terminal is a mobile terminal or a background computer system.

The system realizes the visualization of data and the lightweight of management, formulates an expected solution to reduce the working difficulty, enlarges the working environment range, and has the excellent characteristics of convenient carrying, visualized operation and the like if being a mobile terminal.

Example 2

As shown in fig. 2, based on the above system, the present solution further provides a monitoring control method of an anti-seepage monitoring system based on a terminal, which includes the following steps:

(1) setting a normal parameter range and a standard video image through a terminal, and sending information to a main control device;

(2) the main control equipment acquires a real-time video image of a site through image monitoring equipment arranged on the site, and acquires a real-time environment parameter value of the site through a dehumidification anti-seepage device which is arranged on the site and has the functions of measurement and transmission; and the real-time environment parameter value is displayed on the terminal equipment in a line graph form.

(3) The main control equipment compares the real-time environment parameter value with a set parameter range and judges whether the environment state is abnormal or not;

if the real-time environment parameter value falls into the set parameter range, judging the real-time environment parameter value to be normal; sending information to a terminal, and displaying a normal prompt on the terminal; if the real-time environment parameter value is out of the set parameter range, sending information to the terminal, and displaying abnormal prompts on the terminal;

comparing the real-time video image with the set video image, if the real-time video image is consistent with the set video image, sending information to the terminal, and displaying a normal prompt on the terminal; if the two are inconsistent, sending information to the terminal, and displaying abnormal prompts on the terminal;

the method for acquiring the set parameter range of the environmental parameter values is to adopt the anti-seepage equipment to measure the environmental parameter values at a specific time, wherein the period can be 3 days, 5 days or a period of a week, a month and the like, and after eliminating the environmental parameter values with large differences, the rest parameter values are averaged to obtain the environmental parameter values. When the abnormal real-time environment parameter value is displayed on the terminal, the abnormal real-time environment parameter value is displayed in two modes of characters and a line graph, so that a user can conveniently check the abnormal real-time environment parameter value through a client side and perform corresponding operation;

comparing the real-time video image with the set video image, and if the real-time video image is consistent with the set video image, displaying the video on the terminal normally; if the video images are inconsistent, displaying video abnormity on the terminal, and displaying abnormal real-time video images; the method for acquiring the set video images is consistent with the method for acquiring the set environmental parameter values, the video images of the specific time which can be 3 days, 5 days or a period of a week, a month and the like are measured by a camera, and after the video images with large individual differences are removed, the residual video images are averaged to obtain the video images. During measurement, if the measured video image is normal, the original video image is continuously displayed on the terminal display to reduce the flow required by image updating, and the video image is displayed and updated on the terminal only when the video image is abnormal.

The abnormal real-time environment parameter value and/or the abnormal real-time video image displayed by the terminal are used for judging the site problems, the site state is as follows,

(a) if the real-time field environment parameter value is continuously 0, the terminal displays normal video;

(b) if the real-time field environment parameter value jumps in a large range, the terminal displays normal video;

(c) if the real-time field environment parameter value jumps in a large range, and the terminal displays abnormal video;

(d) and if the real-time field environment parameter value is continuously a constant value, the terminal displays normal video.

(4) According to the abnormal real-time environment parameter values displayed by the terminal, the terminal judges the field problems, provides a solution, selects the terminal solution to carry out the step (5), selects a manual solution and enters the step (6);

judging the parameter value first, because the parameter value is most accurate, such as: setting the measured humidity value range of the node to be (0-100), wherein the normal value range is (40-90), and comparing the measured value with the normal value range, wherein the following conditions are provided:

the measured values are in the normal range: the external environment humidity is normal; deviation from the boundary of the normal range of values but within the normal range of values: the external environment is humid, and a user can select whether to prevent seepage and dehumidify through the terminal; when the temperature of the equipment deviates to the limit, the humidity sensor measures the boundary numerical value (the upper limit is 100: water coverage, the lower limit is 0: sensor damage), real-time monitoring is carried out through a camera, and whether the equipment is damaged or not is judged manually.

If the parameters are abnormal, the image is adopted for judgment, and the following conditions are observed:

measurement module, main control computer smoking or shell warp: the high temperature accumulation in the machine is not scattered or is caused by short circuit high temperature, and the equipment is reported to be burnt and damaged; gather the monitoring module, the power lamp of main control computer is unusual to flicker: the flicker frequency is not changed or extinguished, and the power supply problem is solved; gather the monitoring module, the abnormal scintillation of program monitoring lamp of main control computer: the flicker frequency is not changed or extinguished, and the problems of programs or sensors or communication are solved; the movable acquisition module can not move at regular time, the movement cannot be seen in the image for a long time, the power lamp is good, the motor or the circuit or the track has faults, and if the power lamp is bad, the power supply circuit is bad.

When the image is abnormal, manual judgment is carried out, and a corresponding specific solution is adopted for processing.

(5) According to the solution, the terminal generates a corresponding signal and sends the signal to the main control equipment, and the main control equipment controls the image monitoring equipment and the dehumidification seepage-proofing device to set so as to solve the problem;

(6) and prompting manual field solution according to the solution. And 5, 6, uploading the obtained field problems and the provided corresponding solutions to a cloud server. The system can also comprise a cloud server, corresponding problems are uploaded, a more comprehensive database of the problems and schemes is obtained, and a better solution is obtained. The field problem and corresponding solution are uploaded to the server and stored in the server to form a complete fault record about the anti-seepage device, so as to facilitate later statistics, maintenance and the like. The method also can comprise the process that the terminal sends reports to the server according to the obtained problem processing results. The report contains a request for whether the problem was resolved and whether professional assistance is required. If the terminal user can not solve the field problem, professional staff can be requested to help through the report; if the terminal user solves the field problem, the sent report is stored in the server, so that the later calling and checking are facilitated. The corresponding solution is obtained, the problem is solved in an instructive way, the blindness of solving the problem by a common user is reduced, or the problem is solved by a professional worker, so that the method is convenient and quick, and the manpower and material resources are saved; when needing to be noticed, when a common user goes to the site to solve the problem according to the solution indicated by the terminal, the power supply and the circuit on the site are required to be ensured to be in working states.

Example 3

Embodiment 3 is basically the same as embodiment 2, and is characterized in that the abnormal real-time environment parameter value and/or the abnormal real-time video image displayed by the terminal is used for judging the site problem, the site state is more concretely as follows,

(a) if the real-time field environment parameter value is continuously 0, but the terminal displays a normal video, judging whether the first device is damaged, and displaying a solution by the terminal, wherein the method specifically comprises the following steps:

the terminal observes whether the surface of the equipment with the measuring and transmitting functions is damaged or not in real time through the camera;

if the surface damage exists, the terminal displays a first solution;

if the surface damage does not exist, a restarting operation instruction is sent to the first equipment through the terminal and used for triggering the first equipment to acquire and transmit the real-time environment parameter value again;

if the terminal obtains the real-time environment parameter value of the site again through the first equipment arranged on the site, the display problem of the terminal is remotely solved; if the terminal cannot acquire the real-time environment parameter value of the site again through the first equipment arranged on the site, the terminal displays a second solution;

(b) if the real-time field environment parameter value jumps in a large range, but the terminal displays a normal video, judging whether the first equipment is damaged, and displaying a solution by the terminal, wherein the method specifically comprises the following steps:

the terminal observes whether the surface of the equipment with the measuring and transmitting functions is damaged or not in real time through the camera;

if the surface damage exists, the terminal displays a first solution; and manually moving to the site to replace or repair the first equipment.

If the surface damage does not exist, a restarting operation instruction is sent to the first equipment through the terminal and used for triggering the first equipment to acquire and transmit the real-time environment parameter value again;

if the terminal obtains the real-time environment parameter value of the site again through the first equipment arranged on the site, the display problem of the terminal is remotely solved; if the terminal cannot acquire the real-time environment parameter value of the site again through the first equipment arranged on the site, the terminal displays a second solution; manually go to the site to inspect, repair or replace the first device.

(c) If the real-time field environment parameter value jumps in a large range and the terminal displays abnormal videos, the terminal displays a third solution; a third solution is to manually go to the site to inspect the environment, inspect, repair or replace the first device.

(d) If the real-time field environment parameter value is continuously a constant value, but the video displayed by the terminal is normal, the terminal sends a parameter acquisition instruction to the first equipment, and the parameter acquisition instruction is used for triggering the first equipment to acquire the real-time field environment parameter value;

if the real-time field environment parameter value displayed by the terminal changes and the terminal obtains the latest parameter reply instruction sent by the first equipment, the problem of terminal display is solved;

if the real-time field environment parameter value displayed by the terminal is not changed, but the terminal obtains the latest parameter reply instruction sent by the first device, the terminal displays a fourth solution; manually go to the site to inspect, repair or replace the portion of the first device used for data transmission.

And if the real-time field environment parameter value displayed by the terminal is not changed and the terminal does not obtain the latest parameter reply instruction sent by the first equipment, displaying a fifth solution by the terminal. Manually go to the site to inspect, repair or replace the portion of the first device used for data acquisition.

The above solution can be set according to the requirement, for example, the control can be performed through the terminal, and the corresponding device is restarted to solve the problem.

Example 4

Based on the embodiment 2, the embodiment 4 further includes that the main control device in the step (3) calculates the real-time environment parameter value acquired by the dehumidification and anti-seepage device to obtain a real-time monitoring value, and the real-time environment parameter value is compared with the set parameter range.

The specific method for acquiring data is as follows: (A) the method comprises the steps that a main control device obtains first data, wherein the first data are obtained by processing humidity acquired by a first acquisition device and/or a first acquisition standby device;

(A1) the main control equipment transmits a data acquisition instruction to each first acquisition equipment, and triggers each first acquisition equipment to acquire and process data to obtain first data;

the main control equipment transmits a data sending instruction to each first acquisition equipment, and triggers each first acquisition equipment to send the first data;

(A2) the main control device judges whether the first data is received, if so, the step (A3) is carried out; if not, go to step (A4);

(A3) if the main control equipment judges whether the first data is accurate, if so, storing the first data for later use, and entering the step (3); if not, entering the step (A4);

(A4) the main control equipment transmits a data acquisition instruction to the first acquisition standby equipment, and triggers the first acquisition standby equipment to acquire and process data to obtain first data;

the main control equipment transmits a data sending instruction to the first acquisition standby equipment and triggers the first acquisition standby equipment to send the first data;

(A5) after the step (a4), the process returns to the step (a2) to make a judgment.

The step of processing the data by the first acquisition equipment and/or the first acquisition standby equipment to obtain the first data is as follows: the following calculation was used:

wherein Hum_{Fixing device}For fixed acquisition Point integrated humidity, the first data is Hum_{Fixing device}N is naturalThe number of the fixed acquisition points is represented, i represents the ith fixed acquisition point, Noni represents the humidity acquired by a sensor on first acquisition equipment and/or first acquisition standby equipment on the ith fixed acquisition point, and Hum_{Null 0}The expected value of the air humidity of the space to be measured is obtained.

(B) The main control equipment acquires second data, wherein the second data is obtained by processing the humidity acquired by the second acquisition equipment;

(B1) the main control equipment sends a movement control starting instruction to the movement controller to control the second acquisition equipment to move according to a set path;

after the time T is reached, the main control equipment sends a movement control ending instruction to the movement controller to control the second acquisition equipment to stop moving;

(B2) in time T, the main control equipment transmits a data acquisition instruction to the second acquisition equipment according to an interval period T1, and the second acquisition equipment is triggered to acquire and process data to obtain second data;

the main control equipment transmits a data sending instruction to the second acquisition equipment according to an interval period t1, and triggers the second acquisition equipment to send the second data; .

And the main control equipment receives the second data and stores the second data for later use.

The step of the second acquisition device performing data processing to obtain second data is as follows: the following calculation was used:

wherein, Y represents the total number of the positions of a certain movable acquisition point at different heights of the wall surface, j represents the jth position measured by the movable acquisition point, Nodej represents the humidity acquired by a sensor on the second acquisition equipment at the jth position, and NHum_OffsetAcquisition Point for each move relative to Hum_{Null 0}A deviation of (a);

wherein Hum_OffsetFor moving acquisition point relative Hum_{Null 0}K is a natural number and represents the kth mobile acquisition point, M is a natural number and represents the total number of the mobile acquisition points, NHum_OffsetAcquisition Point for each move relative to Hum_{Null 0}Deviation of (1), NHumk_OffsetThe calculation formula is NHum_OffsetThe calculation formula of (2).

Hum_{Moving device}＝Hum_{Null 0}+Hum_Offset；

Wherein Hum_{Moving device}For moving collection points to synthesize humidity, Hum_{Moving device}As second data, Hum_{Null 0}For the expected value of the air humidity of the space to be measured, Hum_OffsetFor moving acquisition point relative Hum_{Null 0}The combined deviation of (2).

(3) And the main control equipment processes the first data and the second data to obtain a monitoring value.

The main control equipment processes the first data and the second data to obtain a monitoring value, and the following calculation is adopted:

Hum_{air (a)}＝Hum_{Null 0}+Hum_{Air bias}；

Wherein Hum_{Air (a)}For the integrated humidity of the air in the space to be measured, Hum_{Air (a)}For monitoring values, Hum_{Air bias}Is the integrated deviation of the integrated humidity of the air in the space to be measured, Hum_{Null 0}The expected value of the air humidity of the space to be measured is obtained;

wherein Hum_OffsetFor moving acquisition points relative to Hum_{Null 0}Integrated deviation of (Hum)_{Deviation from fixation}For fixed acquisition points relative to Hum_{Null 0}The comprehensive deviation of (2);

wherein Hum_{Deviation from fixation}For fixed acquisition points relative to Hum_{Null 0}N is a natural number, N represents the number of fixed acquisition points, i represents the ithThe node i represents humidity acquired by a first acquisition device on the ith fixed acquisition point and/or a sensor on first acquisition standby equipment;

wherein Hum_OffsetFor moving acquisition points relative to Hum_{Null 0}K is a natural number and represents the kth mobile acquisition point, M is a natural number and represents the total number of the mobile acquisition points, NHum_OffsetAcquisition Point for each move relative to Hum_{Null 0}A deviation of (a);

y represents the total number of the positions of a certain movable acquisition point at different heights of the wall surface, Y is a natural number, j represents the jth position measured by the movable acquisition point, and Nodej represents the humidity acquired by a sensor on the second acquisition equipment at the jth position.

This scheme is through Hum_{Air (a)}The comparison between the set value and the real-time detection value judges whether the corresponding site has the condition or not, and whether the whole system runs normally or not.

The invention and its embodiments have been described above schematically, without limitation, and the invention can be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The representation in the drawings is only one of the embodiments of the invention, the actual construction is not limited thereto, and any reference signs in the claims shall not limit the claims concerned. Therefore, if a person skilled in the art receives the teachings of the present invention, without inventive design, a similar structure and an embodiment to the above technical solution should be covered by the protection scope of the present patent. Furthermore, the word "comprising" does not exclude other elements or steps, and the word "a" or "an" preceding an element does not exclude the presence of a plurality of such elements. Several of the elements recited in the product claims may also be implemented by one element in software or hardware. The terms first, second, etc. are used to denote names, but not any particular order.

Claims (8)

1. The utility model provides an antiseepage monitored control system based on terminal which characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

the image monitoring equipment is used for acquiring field images;

the dehumidification seepage-proofing device is used for collecting field environment parameters; the dehumidification seepage-proofing device comprises first acquisition equipment fixedly arranged on the wall of the space to be detected and second acquisition equipment longitudinally moving along the wall of the space to be detected;

the main control equipment receives the information of the image monitoring equipment and the dehumidification anti-seepage device, processes the received information of the image monitoring equipment and the dehumidification anti-seepage device, and returns a terminal control signal to the image monitoring equipment and the dehumidification anti-seepage device; the main control equipment calculates the collected real-time environment parameter value to obtain a real-time monitoring value, and the real-time environment parameter value is compared with a set parameter range; judging whether the environmental state is abnormal or not;

(A) the method comprises the steps that a main control device obtains first data, wherein the first data are obtained after humidity acquired by a first acquisition device is processed;

the step of the first acquisition equipment for data processing to obtain first data is as follows: the following calculation was used:

wherein Hum_{Fixing device}The data is first data which is expressed as the comprehensive humidity of fixed acquisition points, N is a natural number which is expressed as the number of the fixed acquisition points, i is the ith fixed acquisition point, Node i is the humidity acquired by a sensor on first acquisition equipment and/or first acquisition standby equipment on the ith fixed acquisition point, Hum_{Null 0}For the desired value of the air humidity of the space to be measured；

(B) The main control equipment acquires second data, wherein the second data is obtained by processing the humidity acquired by the second acquisition equipment;

the step of the second acquisition device performing data processing to obtain second data is as follows: the following calculation was used:

wherein, Y represents the total number of the positions of a certain movable acquisition point at different heights of the wall surface, j represents the jth position measured by the movable acquisition point, Nodej represents the humidity acquired by a sensor on the second acquisition equipment at the jth position, and NHum_OffsetAcquisition Point for each move relative to Hum_{Null 0}A deviation of (a);

wherein Hum_OffsetFor moving acquisition point relative Hum_{Null 0}K is a natural number and represents the kth mobile acquisition point, M is a natural number and represents the total number of the mobile acquisition points, NHum_OffsetAcquisition Point for each move relative to Hum_{Null 0}Deviation of (1), NHumk_OffsetThe calculation formula is NHum_OffsetThe calculation formula of (2);

Hum_{moving device}＝Hum_{Null 0}+Hum_Offset；

Wherein Hum_{Moving device}Is the second data, expressed as the moving acquisition Point integrated humidity, Hum_{Null 0}For the expected value of the air humidity of the space to be measured, Hum_OffsetFor moving acquisition point relative Hum_{Null 0}The comprehensive deviation of (2);

(C) the main control equipment adopts the NHum in the step (B)_OffsetThe value is calculated to obtain the monitoring value,

the following calculation was used:

Hum_{air (a)}＝Hum_{Null 0}+Hum_{Air bias}；

Wherein Hum_{Air (a)}For monitoring values, expressed as the integrated humidity of the air in the space to be measured, Hum_{Air bias}Is the integrated deviation of the integrated humidity of the air in the space to be measured, Hum_{Null 0}The expected value of the air humidity of the space to be measured is obtained;

wherein Hum_OffsetFor moving acquisition points relative to Hum_{Null 0}Integrated deviation of (Hum)_{Deviation from fixation}For fixed acquisition points relative to Hum_{Null 0}The comprehensive deviation of (2);

wherein Hum_{Deviation from fixation}For fixed acquisition points relative to Hum_{Null 0}The comprehensive deviation of the data acquisition system is shown as the following steps, wherein N is a natural number, N represents the number of fixed acquisition points, i represents the ith fixed acquisition point, and Nodei represents the humidity acquired by a first acquisition device on the ith fixed acquisition point and/or a sensor on first acquisition standby equipment;

wherein Hum_OffsetFor moving acquisition points relative to Hum_{Null 0}K is a natural number and represents the kth mobile acquisition point, M is a natural number and represents the total number of the mobile acquisition points, NHum_OffsetAcquisition Point for each move relative to Hum_{Null 0}A deviation of (a);

y represents the total number of the positions of a certain movable acquisition point at different heights of the wall surface, Y is a natural number, j represents the jth position measured by the movable acquisition point, and Nodej represents the humidity acquired by a sensor on second acquisition equipment at the jth position;

if it is in real timeEnvironmental parameter value Hum_{Fixing device}，Hum_{Moving device}，Hum_{Air (a)}If the parameter falls into the set parameter range, judging the condition is normal; sending information to a terminal, and displaying a normal prompt on the terminal; if the real-time environment parameter value is out of the set parameter range, sending information to the terminal, and displaying abnormal prompts on the terminal;

comparing the real-time video image with the set video image, if the real-time video image is consistent with the set video image, sending information to the terminal, and displaying a normal prompt on the terminal; if the two are inconsistent, sending information to the terminal, and displaying abnormal prompts on the terminal;

and the terminal receives the information sent by the main control equipment and returns the control information to the main control equipment.

2. The terminal-based seepage-proofing monitoring system of claim 1, wherein: the image monitoring equipment comprises a plurality of cameras, and the cameras are arranged on an engineering site.

3. The terminal-based seepage-proofing monitoring system of claim 1, wherein: the second collecting device moving longitudinally along the wall of the space to be detected is arranged on the moving carrier, the rail is arranged on the wall of the space to be detected, and the moving carrier moves on the rail.

4. A terminal-based seepage prevention monitoring system according to claim 1 or 3, wherein: the terminal is a mobile terminal or a background computer system.

5. A monitoring control method of an anti-seepage monitoring system based on a terminal comprises the following steps:

(1) setting a normal parameter range and a standard video image through a terminal, and sending information to a main control device;

(2) the main control equipment acquires a real-time video image of a site through image monitoring equipment arranged on the site, and acquires a real-time environment parameter value of the site through a dehumidification anti-seepage device which is arranged on the site and has the functions of measurement and transmission; the dehumidification seepage-proofing device comprises first acquisition equipment fixedly arranged on the wall of the space to be detected and second acquisition equipment longitudinally moving along the wall of the space to be detected;

(3) the main control equipment calculates the collected real-time environment parameter value to obtain a real-time monitoring value, and the real-time environment parameter value is compared with a set parameter range; judging whether the environmental state is abnormal or not;

(A) the method comprises the steps that a main control device obtains first data, wherein the first data are obtained after humidity acquired by a first acquisition device is processed;

the step of the first acquisition equipment for data processing to obtain first data is as follows: the following calculation was used:

wherein Hum_{Fixing device}The data is first data which is expressed as the comprehensive humidity of fixed acquisition points, N is a natural number which is expressed as the number of the fixed acquisition points, i is the ith fixed acquisition point, Node i is the humidity acquired by a sensor on first acquisition equipment and/or first acquisition standby equipment on the ith fixed acquisition point, Hum_{Null 0}The expected value of the air humidity of the space to be measured is obtained;

(B) the main control equipment acquires second data, wherein the second data is obtained by processing the humidity acquired by the second acquisition equipment;

the step of the second acquisition device performing data processing to obtain second data is as follows: the following calculation was used:

wherein, Y represents the total number of the positions of a certain movable acquisition point at different heights of the wall surface, j represents the jth position measured by the movable acquisition point, Nodej represents the humidity acquired by a sensor on the second acquisition equipment at the jth position, and NHum_OffsetAcquisition Point for each move relative to Hum_{Null 0}A deviation of (a);

wherein Hum_OffsetFor moving acquisition point relative Hum_{Null 0}K is a natural number and represents the kth mobile acquisition point, M is a natural number and represents the total number of the mobile acquisition points, NHum_OffsetAcquisition Point for each move relative to Hum_{Null 0}Deviation of (1), NHumk_OffsetThe calculation formula is NHum_OffsetThe calculation formula of (2);

Hum_{moving device}＝Hum_{Null 0}+Hum_Offset；

Wherein Hum_{Moving device}Is the second data, expressed as the moving acquisition Point integrated humidity, Hum_{Null 0}For the expected value of the air humidity of the space to be measured, Hum_OffsetFor moving acquisition point relative Hum_{Null 0}The comprehensive deviation of (2);

(C) the main control equipment adopts the NHum in the step (B)_OffsetAnd (3) obtaining a monitoring value through calculation, wherein the following calculation is adopted:

Hum_{air (a)}＝Hum_{Null 0}+Hum_{Air bias}；

Wherein Hum_{Air (a)}For monitoring values, expressed as the integrated humidity of the air in the space to be measured, Hum_{Air bias}Is the integrated deviation of the integrated humidity of the air in the space to be measured, Hum_{Null 0}The expected value of the air humidity of the space to be measured is obtained;

wherein Hum_OffsetFor moving acquisition points relative to Hum_{Null 0}Integrated deviation of (Hum)_{Deviation from fixation}For fixed acquisition points relative to Hum_{Null 0}The comprehensive deviation of (2);

wherein Hum_{Deviation from fixation}For fixed acquisition points relative to Hum_{Null 0}Combined deviation ofN is a natural number, N represents the number of fixed acquisition points, i represents the ith fixed acquisition point, and Nodei represents the humidity acquired by a sensor on first acquisition equipment and/or first acquisition standby equipment on the ith fixed acquisition point;

wherein Hum_OffsetFor moving acquisition points relative to Hum_{Null 0}K is a natural number and represents the kth mobile acquisition point, M is a natural number and represents the total number of the mobile acquisition points, NHum_OffsetAcquisition Point for each move relative to Hum_{Null 0}A deviation of (a);

y represents the total number of the positions of a certain movable acquisition point at different heights of the wall surface, Y is a natural number, j represents the jth position measured by the movable acquisition point, and Nodej represents the humidity acquired by a sensor on second acquisition equipment at the jth position;

if real time environment parameter value Hum_{Fixing device}，Hum_{Moving device}，Hum_{Air (a)}If the parameter falls into the set parameter range, judging the condition is normal; sending information to a terminal, and displaying a normal prompt on the terminal; if the real-time environment parameter value is out of the set parameter range, sending information to the terminal, and displaying abnormal prompts on the terminal;

comparing the real-time video image with the set video image, if the real-time video image is consistent with the set video image, sending information to the terminal, and displaying a normal prompt on the terminal; if the two are inconsistent, sending information to the terminal, and displaying abnormal prompts on the terminal;

(4) according to the abnormal real-time environment parameter values displayed by the terminal, the terminal judges the field problems, provides a solution, selects the terminal solution to carry out the step (5), selects a manual solution and enters the step (6);

(5) according to the solution, the terminal generates a corresponding signal and sends the signal to the main control equipment, and the main control equipment controls the image monitoring equipment and the dehumidification seepage-proofing device to set so as to solve the problem;

(6) and prompting manual field solution according to the solution.

6. The monitoring control method of the terminal-based anti-seepage monitoring system according to claim 5, characterized in that: judging the site problems of the abnormal real-time environment parameter values and/or the abnormal real-time video images displayed by the terminal in the step (3), wherein the site states are as follows,

(a) if the real-time field environment parameter value is continuously 0, the terminal displays normal video;

(b) if the real-time field environment parameter value jumps in a large range, the terminal displays normal video;

(c) if the real-time field environment parameter value jumps in a large range, and the terminal displays abnormal video;

(d) and if the real-time field environment parameter value is continuously a constant value, the terminal displays normal video.

7. The monitoring control method of the terminal-based anti-seepage monitoring system according to claim 5, characterized in that: and the real-time environment parameter value is displayed on the terminal equipment in a line graph form.

8. The monitoring control method of the terminal-based anti-seepage monitoring system according to claim 5, characterized in that: the steps (5) and (6) further comprise a process of uploading the obtained field problems and the provided corresponding solutions to the cloud server.

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