CN112083861B - Flexible direct-current valve control information acquisition and judgment device and information acquisition and judgment method - Google Patents

Abstract

The invention discloses a flexible direct-current valve control information acquisition and judgment auxiliary tool and an information acquisition and judgment method, wherein the auxiliary tool comprises hardware equipment and an APP (application); the method comprises the following steps: valve control information image acquisition: opening an APP, clicking an image acquisition function, photographing an information page according to a certain sequence, and after the image is clear and complete, "determining" and storing; confirming the information of a main set of the system; collecting the number of newly added modules of each bridge arm; generating a correct SER bypass module matrix; determining a newly added module matrix of a bypass; repeating the operation S5 until all the newly added module matrixes of the bypass are determined; valve control main sleeve bypass state statistics: and merging and organizing the bypass module information matrix and the newly-added bypass module information matrix of each bypass formed in the S5 and the S6 into a unified bypass module information matrix and a newly-added bypass module information matrix. The auxiliary tool and the method can improve the comprehensiveness, the correctness and the efficiency of information acquisition and judgment.

Description

Flexible direct-current valve control information acquisition and judgment device and information acquisition and judgment method

Technical Field

The invention relates to the technical field of flexible direct current power transmission, in particular to a flexible direct current valve control information acquisition and judgment device and a flexible direct current valve control information acquisition and judgment method.

Background

The valve control system is the central nerve of the flexible direct current transmission system, and the function of the flexible direct current converter valve completely depends on complex and flexible control protection to realize flexible direct current valve control. However, the valve control system has the following problems in the operation process, especially under the condition that the amount of information generated by flexible and direct valve control such as power failure and power restoration and accident handling is large:

(1) data needs to be acquired on a plurality of interfaces respectively, so that the information is more, the flow is more, and the error risk is higher. In the processes of power restoration, fault tripping and the like, the state and fault information of each power module, whether the power module is a black module, whether the power module is an original fault module and the like need to be counted. The collection and statistics of such information currently rely on manual multiple interfaces to collect collation records one by one. Especially under the condition of tripping, a large amount of information and interfaces are switched repeatedly, the risks of missed statistics and error statistics exist, the statistical efficiency is low, and the timely reporting and processing of accidents are influenced.

(2) The analysis and statistics of the information are not efficient. After the statistics of the valve control information, classification analysis is required. For example, which modules are newly added with faults, the reasons of the module faults can be confirmed only through code translation, which types of faults exist and the like need to be analyzed and confirmed one by one, and the processes need to be confirmed after some professionals look up relevant data.

(3) And after the overhaul is finished, the parameter checking work data is more. Unlike conventional protection systems, the valvular control system does not allow the associated parameter settings to be checked by way of printed settings and reports. Currently recording is mainly done by taking a picture. After the picture is taken, the picture needs to be exported in time, and related numerical values are sorted, so that the whole process is complicated.

(4) Historical data is not statistically efficient. The historical fault data statistics of gentle straight power module mainly relies on the manual work to develop at present, and power module is in large quantity, and efficiency has the promotion to improve the space.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a flexible direct current valve control information acquisition and judgment device and a flexible direct current valve control information acquisition and judgment method.

The invention discloses a flexible direct-current valve control information acquisition and judgment device and an information acquisition and judgment method, wherein the device comprises hardware equipment and an APP (application), the hardware equipment is movable equipment with an android system, and the APP is installed on the hardware equipment; the information acquisition and judgment method comprises the following steps:

s1: valve control information image acquisition: opening an APP, clicking an image acquisition function, photographing an information page according to a certain sequence, and after the image is clear and complete, "determining" and storing;

s2: confirming the information of the main set of the system:

s2.1: main use set information acquisition: photographing is carried out on the valve control monitoring interface, lamp state display of a working state, an on-duty state and a valve control state is extracted, and correct extracted data is confirmed;

s2.2: judging the information of the main sleeve: comparing the information of the main system set with the information collected in the step S1, and if the information of the main system set is consistent with the information collected in the step S3; if not, clicking the previous step to return to S1 for re-photographing and extracting;

s3: collecting the number of newly added modules of each bridge arm:

s3.1: collecting data of each bridge arm: filling the bypass number of each bridge arm collected in S1 into a bypass module number matrix;

s3.1: calculating the number of newly added bypass modules of each bridge arm: subtracting the number of the bypass of each bridge arm at the same position at the last time from the current time, inputting the subtracted result into a bypass module number increasing matrix, and displaying the number of the bypass modules increased by each bridge arm;

s4: generating the correct SER bypass module matrix:

s4.1: inputting data: manually inputting the number of the collected bypass modules added to each bridge arm into an SER interface of a main sleeve of the system;

s4.2: information calibration: comparing the input data with the bypass number increased by each bridge arm acquired in S3, and if the number comparison is incorrect, manually modifying until a correct SER bypass module matrix passing the comparison is obtained;

s5: determining a newly added module matrix of a bypass:

s5.1: valve control main sleeve bypass state interface information acquisition:

extracting a bypass unit number and a bypass fault code, directly filling the bypass unit number and the bypass fault code into a module information matrix, comparing the filled information with the number of bypass modules corresponding to a bypass module number matrix in S3, prompting if the number of the bypass modules is unequal, and revising the input information until the comparison is passed to form a bypass module information matrix;

s5.2: valve control main set bypass state newly-added module statistics:

obtaining different parts of a last bypass module information matrix and a current bypass module information matrix to generate a newly added bypass module information matrix;

comparing the newly added bypass module information matrix with the corresponding newly added bypass module unit number in the SER bypass module matrix in S4, if the newly added bypass module information matrix is different from the SER bypass module matrix, prompting, directly filling different information into the newly added bypass module information matrix and marking red to form a newly added bypass module information matrix;

s6: repeating the operation S5 until all the newly added module matrixes of the bypass are determined;

s7: valve control main sleeve bypass state statistics: and merging and organizing the bypass module information matrix and the newly-added bypass module information matrix of each bypass formed in the S5 and the S6 into a unified bypass module information matrix and a newly-added bypass module information matrix.

According to an embodiment of the invention, the hardware device is a mobile phone or a tablet computer with a camera function.

The flexible direct-current valve control information acquisition and judgment device and the information acquisition and judgment method have the following beneficial effects: the valve control information acquisition and judgment are realized through a terminal with image identification, and the terminal has corresponding copying steps and an identification program. The comprehensiveness, accuracy and efficiency of information acquisition and judgment are improved.

Detailed Description

In the following description, for purposes of explanation, numerous implementation details are set forth in order to provide a thorough understanding of the various embodiments of the present invention. It should be understood, however, that these implementation details are not to be interpreted as limiting the invention. That is, in some embodiments of the invention, such implementation details are not necessary. In addition, some conventional structures and components are shown in simplified schematic form in the drawings.

In addition, the descriptions related to the first, the second, etc. in the present invention are only used for description purposes, do not particularly refer to an order or sequence, and do not limit the present invention, but only distinguish components or operations described in the same technical terms, and are not understood to indicate or imply relative importance or implicitly indicate the number of indicated technical features. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

The invention discloses a flexible direct-current valve control information acquisition and judgment device and an information acquisition and judgment method, wherein the device comprises hardware equipment and an APP (application), the hardware equipment is movable equipment with an android system, the APP is installed on the hardware equipment, and the hardware equipment is a mobile phone or a tablet computer with a camera function; the information acquisition and judgment method comprises the following steps:

s1: valve control information image acquisition: opening an APP, clicking an image acquisition function, photographing an information page according to a certain sequence, and after the image is clear and complete, "determining" and storing;

s2: confirming the information of the main set of the system:

s2.1: main use set information acquisition: photographing is carried out on the valve control monitoring interface, lamp state display of a working state, an on-duty state and a valve control state is extracted, and correct extracted data is confirmed;

s2.2: judging the information of the main sleeve: comparing the information of the main system set with the information collected in the step S1, and if the information of the main system set is consistent with the information collected in the step S3; if not, clicking the previous step to return to S1 for re-photographing and extracting;

s3: collecting the number of newly added modules of each bridge arm:

s3.1: collecting data of each bridge arm: filling the bypass number of each bridge arm collected in S1 into a bypass module number matrix;

s3.1: calculating the number of newly added bypass modules of each bridge arm: subtracting the number of the bypass of each bridge arm at the same position at the last time from the current time, inputting the subtracted result into a bypass module number increasing matrix, and displaying the number of the bypass modules increased by each bridge arm;

s4: generating the correct SER bypass module matrix:

s4.1: inputting data: manually inputting the number of the collected bypass modules added to each bridge arm into an SER interface of a main sleeve of the system;

s4.2: information calibration: comparing the input data with the bypass number increased by each bridge arm acquired in S3, and if the number comparison is incorrect, manually modifying until a correct SER bypass module matrix passing the comparison is obtained;

s5: determining a newly added module matrix of a bypass:

s5.1: valve control main sleeve bypass state interface information acquisition:

extracting a bypass unit number and a bypass fault code, directly filling the bypass unit number and the bypass fault code into a module information matrix, comparing the filled information with the number of bypass modules corresponding to a bypass module number matrix in S3, prompting if the number of the bypass modules is unequal, and revising the input information until the comparison is passed to form a bypass module information matrix;

s5.2: valve control main set bypass state newly-added module statistics:

obtaining different parts of a last bypass module information matrix and a current bypass module information matrix to generate a newly added bypass module information matrix;

comparing the newly added bypass module information matrix with the corresponding newly added bypass module unit number in the SER bypass module matrix in S4, if the newly added bypass module information matrix is different from the SER bypass module matrix, prompting, directly filling different information into the newly added bypass module information matrix and marking red to form a newly added bypass module information matrix;

s6: repeating the operation S5 until all the newly added module matrixes of the bypass are determined;

s7: valve control main sleeve bypass state statistics: and merging and organizing the bypass module information matrix and the newly-added bypass module information matrix of each bypass formed in the S5 and the S6 into a unified bypass module information matrix and a newly-added bypass module information matrix.

Example (b):

take the control of valve in south of the cloud as an example

S1: collecting SER information of the valve control fault of the workstation: photographing SER information of the valve control fault on the Yunnan side at a workstation interface;

s2: confirming the information of the main set of the system:

collecting information of the valve control main set in the cloud south: selecting a Yunnan side valve control main system (on duty state), taking a picture on a valve control monitoring interface, extracting lamp state data of a working state, the on duty state and a valve control state, and directly inputting the lamp state data into a state lamp matrix, wherein input information is as follows: and selecting the working state: green light and light off; on duty status option: green light and light off; valve control state option: green light, red light and light off; the shooting can be carried out again by clicking the 'previous step', and the state lamp matrix state can be corrected by clicking the matrix if an error occurs; confirming the picture and the information, clicking the next step, and entering the next step;

judging the information of the valve control main set at the south of the cloud: and (3) judging according to the data of the last step of information acquisition of the Yunnan side valve control main sleeve:

(1) the working state is as follows: lamp bulb

(2) The duty state: green light on

(3) Valve control state: only self-checking is passed through the green light and all the other lights are turned off

If one of the three judgments is not met, popping up a prompt of 'abnormal valve control information, please check' and extracting by clicking 'previous step' to take a picture again; if the first step and the second step are met, prompting that the information judgment of the Yunnan side valve control main set is correct, and entering the next step by clicking 'confirm' and 'next step';

s3: collecting the number of newly added modules of each bridge arm:

counting the number of the valve control main set bypasses of the cloud south side: extracting the number of the bypasses in the step of 'Yunnan side valve control main set information acquisition' and filling the number of the bypasses into a 'bypass module number matrix', confirming that the number of the bypasses extracted by the picture is correct, comparing the information of the last Yunnan side valve control monitoring interface, recording the number condition of the bypasses, and inputting an information example: AU: (input box); BU: (input box); CU: (input box); AD: (input box); BD: (input box); CD: (input box). After data input is confirmed, clicking 'confirmation' for storage, and clicking 'next step' for entering the next step;

and (3) comparing the bypass numbers of the valve control main sets of the cloud south side: displaying a data matrix in the last step of counting the bypass number of the main bushing controlled by the valve on the Yunnan side, subtracting the bypass number at the same position last time from the bypass number at the current time, inputting the subtraction result into a bypass module number increasing matrix, displaying the number of the bypass modules increased by each bridge arm, and inputting an information example: AU increase: (input box); BU increase: (input box); the CU increases: (input box); AD increased: (input box); BD increased: (input box); CD increase: (input box). And if the data has deviation, modifying, and finally clicking for confirmation.

S4: generating the correct SER bypass module matrix:

collecting SER interface information of the valve control master set in the cloud south: selecting a cloud south side valve control main transportation system (on duty state), taking a picture on a valve control SER interface, confirming that all the information in the time period is taken and recorded completely, and keeping an SER picture;

analyzing and recording SER interface information of the valve control master set in the cloud south: comparing the newly added module number of AU, BU, CU, AD, BD and CD input at this time with the bypass number added by each bridge arm in the step of counting the bypass number of the main bushing controlled by the valve on the Yunnan side, and inputting an information example: AU new bypass module unit number: (input box); BU newly-increased bypass module unit number: (input box); CU newly-added bypass module unit number: (input box); AD newly-increased bypass module unit number: (input box); BD new bypass module unit number: (input box); CD new bypass module unit number: (input box). Firstly, inputting unit numbers and then comparing the numbers; an input matrix is set for the number of the input unit, 26 numbers can be input in each row, and an 'SER bypass module matrix' is generated; if the quantity comparison is incorrect, prompting is carried out, and the next step is carried out after the 'SER bypass module matrix' is modified for confirmation;

S5-S6: determining the newly added module matrixes of all bypasses:

1. determining a newly added module matrix of an AU bypass:

acquiring the information of the bypass state interface of the valve control main set AU of the south of the cloud: selecting a cloud south side valve control main transportation system (on duty state), taking a picture on a valve control AU bypass state interface and confirming that the extracted data is correct:

1) the extracted bypass unit number and bypass fault code are directly filled into an 'AU bypass module information matrix', such as an interface bypass matrix;

2) modifying the input information;

3) the AU value of a bypass module number matrix in the step of counting the bypass number of the main bushing controlled by the valve on the Yunnan side is compared with the number of modules in the interface (the number of bypass units is not the total number of-1), and if the AU value is not equal to the number of the modules in the interface, prompting is carried out, and the information recorded in the previous step can be modified again;

4) confirming an 'AU bypass module information matrix',

5) the method comprises the steps of the previous step, the confirmation, the comparison and the next step, wherein the next step is carried out after the confirmation;

counting by a newly added module of the AU bypass state of the valve control main set of the cloud south side:

1) and (3) taking different parts of the 'last AU bypass module information matrix' and the 'current AU bypass module information matrix' to generate an 'AU newly-added bypass module information matrix'. For example: the last matrix has 12 and 33 bypass modules, and the current matrix has 12, 23 and 24 bypass modules, so that the generated matrices are 33, 23 and 24;

2) and comparing the 'AU newly increased bypass module unit number' in the 'SER bypass module matrix' step of 'analyzing and recording the SER interface information of the main bushing on the Yunnan side valve control' with the module number of the 'AU newly increased bypass module information matrix' in the last step, and prompting if the AU newly increased bypass module unit number is different from the module number of the 'AU newly increased bypass module information matrix' in the last step. Different information is directly filled into an AU newly-increased bypass module information matrix and is marked with red;

3) modifying and confirming an 'AU newly added bypass module information matrix';

4) modify and validate the "AU bypass module information matrix": because the relevant information is newly added, the information of the AU bypass module information matrix in the step of 'acquisition of the AU bypass state interface information of the main bushing controlled by the valve on the Yunnan side' is possibly incorrect, so the information needs to be modified, and the next step is carried out after the modification;

2. determining a newly added module matrix of the BU bypass:

acquiring information of a bypass state interface of a valve control main set BU in a cloud south: selecting a cloud south side valve control main operation system (on duty state), taking a picture on a valve control BU bypass state interface and confirming that extracted data is correct:

1) the extracted bypass unit number and bypass fault code are directly filled into a 'BU bypass module information matrix', such as an interface bypass matrix;

2) modifying the input information;

3) the numerical value of a bypass module number matrix BU in the step of counting the number of the bypasses of the main bushing controlled by the valve on the Yunnan side is compared with the number of the modules in the interface (the number of the bypass units is not the total number of-1), if the numerical values are not equal, prompting is carried out, and the information recorded in the previous step can be modified again;

4) confirm "BU bypass module information matrix";

5) the method comprises the steps of the previous step, the confirmation, the comparison and the next step, wherein the next step is carried out after the confirmation;

newly-added module statistics of BU bypass state of valve control main set in Yunnan side:

1) and taking different parts of the last BU bypass module information matrix and the current BU bypass module information matrix to generate a BU newly-added bypass module information matrix. For example: the last matrix has 12 and 33 bypass modules, and the current matrix has 12, 23 and 24 bypass modules, so that the generated matrices are 33, 23 and 24;

2) comparing the 'BU newly-increased bypass module unit number' in the 'SER bypass module matrix' in the 'SER bypass module information analysis record of the main valve control sleeve SER on the Yunnan side' with the module number of the 'BU newly-increased bypass module information matrix' in the last step, and prompting if the numbers are different. Directly filling different information into a 'BU newly-added bypass module information matrix' and marking the information in red;

3) modifying and confirming 'BU newly added bypass module information matrix';

4) modify and validate the "BU bypass module information matrix": as the relevant information is newly added, the information of the BU bypass module information matrix in the step of 'acquiring the information of the BU bypass state interface of the main valve control set on the Yunnan side' may be incorrect, so that the information needs to be modified, and the next step is carried out after the modification;

3. determining a newly added module matrix of the CU bypass:

collecting information of a bypass state interface of a valve control main set CU of a cloud south side: selecting a cloud south side valve control main operation system (on duty state), taking a picture on a valve control CU bypass state interface and confirming that extracted data is correct:

1) the extracted bypass unit number and bypass fault code are directly filled into a CU bypass module information matrix, such as an interface bypass matrix;

2) modifying the input information;

3) comparing the CU numerical value of a bypass module number matrix in the step of counting the bypass number of the main bushing of the valve control on the Yunnan side with the number of modules in the interface (the number of bypass units is not the total number of-1), prompting if the number is unequal, and revising the information recorded in the previous step;

4) identifying a "CU bypass Module information matrix";

5) the method comprises the steps of the previous step, the confirmation, the comparison and the next step, wherein the next step is carried out after the confirmation;

counting by newly added modules of bypass states of a valve control main set CU of the cloud south side:

1) and (3) taking different parts of the last CU bypass module information matrix and the current CU bypass module information matrix to generate a CU newly added bypass module information matrix. For example: the last matrix has 12 and 33 bypass modules, and the current matrix has 12, 23 and 24 bypass modules, so that the generated matrices are 33, 23 and 24;

2) and comparing the ' CU newly increased bypass module unit number ' in the ' SER bypass module matrix ' step of ' analyzing and recording the SER interface information of the main bushing on the Yunnan side valve control with the module number of the ' CU newly increased bypass module information matrix ' in the last step, and prompting if the numbers are different. Directly filling different information into a 'CU newly-added bypass module information matrix' and marking the information in red;

3) modifying and confirming 'CU newly added bypass module information matrix';

4) modify and validate the "CU bypass module information matrix": because related information is newly added, the information of the CU bypass module information matrix in the step of 'collecting the information of the CU bypass state interface of the main bushing controlled by the valve on the Yunnan side' is possibly incorrect, so the information needs to be modified, and the next step is carried out after the modification;

4. determining a newly added module matrix of the AD bypass:

acquiring AD bypass state interface information of the valve control master set in the cloud south side: selecting a cloud south side valve control main transportation system (on duty state), taking a picture on a valve control AD bypass state interface and confirming that extracted data is correct:

1) the extracted bypass unit number and bypass fault code are directly filled into an AD bypass module information matrix, such as an interface bypass matrix;

2) modifying the input information;

3) the AD value of a bypass module number matrix in the step of counting the number of the bypasses of the main bushing controlled by the valves on the Yunnan side is compared with the number of the modules in the interface (the number of the bypass units is not the total number of-1), and if the number is unequal, prompting is carried out, and the information recorded in the previous step can be revised again;

4) confirming an AD bypass module information matrix;

5) the method comprises the steps of the previous step, the confirmation, the comparison and the next step, wherein the next step is carried out after the confirmation;

counting the AD bypass state newly added modules of the valve control master set of the cloud south side:

1) and (3) taking different parts of the last AD bypass module information matrix and the current AD bypass module information matrix to generate an AD newly-added bypass module information matrix. For example: the last matrix has 12 and 33 bypass modules, and the current matrix has 12, 23 and 24 bypass modules, so that the generated matrices are 33, 23 and 24;

2) and comparing the AD newly-increased bypass module unit number in the SER bypass module matrix in the step of analyzing and recording the SER interface information of the main bushing on the Yunnan side valve control with the module number of the AD newly-increased bypass module information matrix in the previous step, and prompting if the AD newly-increased bypass module unit number is different from the module number of the SER bypass module information matrix in the last step. Different information is directly filled into an AD newly-added bypass module information matrix and is marked with red;

3) modifying and confirming an AD newly added bypass module information matrix;

4) modify and validate the "AD bypass module information matrix": because related information is newly added, the information of the AD bypass module information matrix in the step of 'acquiring the information of the AD bypass state interface of the main bushing controlled by the valve on the Yunnan side' is possibly incorrect, so the information needs to be modified, and the next step is carried out after the modification;

5. determining a newly added module matrix of the BD bypass:

collecting information of a BD bypass state interface of the valve control main set on the south of the cloud: selecting a cloud south side valve control main operation system (on duty state), taking a picture on a valve control BD bypass state interface and confirming that extracted data is correct:

1) the extracted bypass unit number and the bypass fault code are directly filled into a BD bypass module information matrix, such as an interface bypass matrix;

2) modifying the input information;

3) the BD numerical value of a bypass module number matrix in the step of counting the number of the bypasses of the main bushing controlled by the valve on the Yunnan side is compared with the number of the modules in the interface (the number of the bypass units is not the total number of-1), and if the numbers are unequal, prompting is carried out, and the information recorded in the previous step can be revised again;

4) identifying a "BD bypass Module information matrix";

5) the method comprises the steps of the previous step, the confirmation, the comparison and the next step, wherein the next step is carried out after the confirmation;

counting by a newly added module of the BD bypass state of the valve control main set of the cloud south side:

1) and (3) taking different parts of the last BD bypass module information matrix and the current BD bypass module information matrix to generate a BD newly added bypass module information matrix. For example: the last matrix has 12 and 33 bypass modules, and the current matrix has 12, 23 and 24 bypass modules, so that the generated matrices are 33, 23 and 24;

2) and comparing the 'BD newly-added bypass module unit number' in the 'SER bypass module matrix' in the 'SER bypass module information analysis record' step with the module number of the 'BD newly-added bypass module information matrix' in the previous step, and prompting if the BD newly-added bypass module unit number is different from the module number of the 'SER bypass module information matrix'. Different information is directly filled into a BD newly added bypass module information matrix and is marked with red;

3) modifying and confirming 'BD newly added bypass module information matrix';

4) modify and validate the "BD bypass module information matrix": the information of the ' BD bypass module information matrix ' in the step of ' information acquisition of the BD bypass state interface of the main bushing on the valve control side of Yunnan is incorrect and needs to be modified, and the next step is carried out after the modification;

6. determining a newly added module matrix of the CD bypass:

collecting CD bypass state interface information of the valve control main set at the south of the cloud: selecting a cloud south side valve control main transportation system (on duty state), taking a picture on a valve control CD bypass state interface and confirming that the extracted data is correct:

1) the extracted bypass unit number and bypass fault code are directly filled into a 'CD bypass module information matrix', such as an interface bypass matrix;

2) modifying the input information;

3) the CD value of a bypass module number matrix in the step of counting the number of the bypasses of the main bushing controlled by the valve on the Yunnan side is compared with the number of the modules in the interface (the number of the bypass units is not the total number of-1), and if the number is unequal, prompting is carried out, and the information recorded in the previous step can be revised again;

4) identifying a "CD bypass Module information matrix";

5) the method comprises the steps of the previous step, the confirmation, the comparison and the next step, wherein the next step is carried out after the confirmation;

counting a newly added module of the CD bypass state of the valve control main set of the cloud south side:

1) and (3) taking different parts of the last AD bypass module information matrix and the current CD bypass module information matrix to generate a CD newly added bypass module information matrix. For example: the last matrix has 12 and 33 bypass modules, and the current matrix has 12, 23 and 24 bypass modules, so that the generated matrices are 33, 23 and 24;

2) and comparing the 'CD newly-increased bypass module unit number' in the 'SER bypass module matrix' in the 'SER bypass module information analysis record' step with the module number of the 'CD newly-increased bypass module information matrix' in the previous step, and prompting if the CD newly-increased bypass module unit number is different from the module number of the SER bypass module information matrix in the 'SER bypass module matrix' in the step. Different information is directly filled into the 'CD newly-added bypass module information matrix' and marked with red;

3) modifying and confirming 'CD newly added bypass module information matrix';

4) modify and validate the "CD bypass module information matrix": because the relevant information is newly added, the information of the 'CD bypass module information matrix' in the step of 'the information acquisition of the CD bypass state interface of the main set of the valve control on the Yunnan side' is possibly incorrect, so the information needs to be modified, and the next step is carried out after the modification is confirmed;

s7: valve control main sleeve bypass state statistics:

counting the bypass state of the valve control main set in the cloud south: merging and organizing the newly added bypass module information matrixes in the steps into a newly added bypass module information matrix; and merging and organizing the bypass module information matrixes in the steps into a bypass module information matrix.

The above is merely an embodiment of the present invention, and is not intended to limit the present invention. Various modifications and alterations to this invention will become apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the scope of the claims of the present invention.

Claims (2)

1. The device is characterized by comprising hardware equipment and an APP (application), wherein the hardware equipment is movable equipment with an android system, and the APP is installed on the hardware equipment; the information acquisition and judgment method comprises the following steps:

s1: valve control information image acquisition: opening an APP, clicking an image acquisition function, photographing an information page according to a certain sequence, and after the image is clear and complete, "determining" and storing;

s2: confirming the information of the main set of the system:

s2.1: main use set information acquisition: photographing is carried out on the valve control monitoring interface, lamp state display of a working state, an on-duty state and a valve control state is extracted, and correct extracted data is confirmed;

s2.2: judging the information of the main sleeve: comparing the information of the main system set with the information collected in the step S1, and if the information of the main system set is consistent with the information collected in the step S3; if not, clicking the previous step to return to S1 for re-photographing and extracting;

s3: collecting the number of newly added modules of each bridge arm:

s3.1: collecting data of each bridge arm: filling the bypass number of each bridge arm collected in S1 into a bypass module number matrix;

s3.1: calculating the number of newly added bypass modules of each bridge arm: subtracting the number of the bypass of each bridge arm at the same position at the last time from the current time, inputting the subtracted result into a bypass module number increasing matrix, and displaying the number of the bypass modules increased by each bridge arm;

s4: generating the correct SER bypass module matrix:

s4.1: inputting data: manually inputting the number of the collected bypass modules added to each bridge arm into an SER interface of a main sleeve of the system;

s4.2: information calibration: comparing the input data with the bypass number increased by each bridge arm acquired in S3, and if the number comparison is incorrect, manually modifying until a correct SER bypass module matrix passing the comparison is obtained;

s5: determining a newly added module matrix of a bypass:

s5.1: valve control main sleeve bypass state interface information acquisition:

extracting a bypass unit number and a bypass fault code, directly filling the bypass unit number and the bypass fault code into a module information matrix, comparing the filled information with the number of bypass modules corresponding to a bypass module number matrix in S3, prompting if the number of the bypass modules is unequal, and revising the input information until the comparison is passed to form a bypass module information matrix;

s5.2: valve control main set bypass state newly-added module statistics:

obtaining different parts of a last bypass module information matrix and a current bypass module information matrix to generate a newly added bypass module information matrix;

comparing the newly added bypass module information matrix with the corresponding newly added bypass module unit number in the SER bypass module matrix in S4, if the newly added bypass module information matrix is different from the SER bypass module matrix, prompting, directly filling different information into the newly added bypass module information matrix and marking red to form a newly added bypass module information matrix;

s6: repeating the operation S5 until all the newly added module matrixes of the bypass are determined;

s7: valve control main sleeve bypass state statistics: and merging and organizing the bypass module information matrix and the newly-added bypass module information matrix of each bypass formed in the S5 and the S6 into a unified bypass module information matrix and a newly-added bypass module information matrix.

2. The device and the method for acquiring and judging the flexible direct current valve control information according to claim 1, wherein the hardware equipment is a mobile phone or a tablet computer with a camera function.