CN117974072B

CN117974072B - Processing method and system for vibrating wire type spot welding strain gauge

Info

Publication number: CN117974072B
Application number: CN202410371533.4A
Authority: CN
Inventors: 杨文�; 王敏; 李君�; 叶跃云; 朱进烽
Original assignee: Nanjing Jingsi Engineering Instrument Co ltd
Current assignee: Nanjing Jingsi Engineering Instrument Co ltd
Priority date: 2024-03-29
Filing date: 2024-03-29
Publication date: 2024-06-04
Anticipated expiration: 2044-03-29
Also published as: CN117974072A

Abstract

The invention provides a processing method and a processing system for a vibrating wire spot welding type strain gauge, which are used for invoking a bridge twinning space corresponding to a target bridge, receiving configuration information of a management end on the configuration of the bridge twinning space, and updating the bridge twinning space based on a strain gauge module and the configuration information to obtain an indication twinning space; based on the triggering operation of the strain gauge module in the indication twin space by the installation end, invoking a decomposition module corresponding to the assembly form of the strain gauge module for display, wherein the decomposition module comprises a plurality of sub-model units positioned at decomposition positions; according to the uploading operation of the installation end on the sub-model unit, a form switching strategy is called to update the model of the corresponding decomposition module and the strain gauge module, so as to obtain a verification twin space; and verifying the installation data corresponding to the sub-model units based on the customized verification strategy to obtain detection data, updating the strain gauge modules in the verification twin space according to the detection data to obtain a display twin space, and sending the display twin space to the management end.

Description

Processing method and system for vibrating wire type spot welding strain gauge

Technical Field

The invention relates to a data processing technology, in particular to a processing method and a processing system for a vibrating wire type spot welding strain gauge.

Background

The vibrating wire strain gauge is a strain sensor for measuring by vibrating wires, when the stress in a structure to be measured changes, the strain gauge synchronously senses the deformation, and the deformation is transmitted to the vibrating wires through a front end seat and a rear end seat to be converted into the change of the stress of the vibrating wires, so that the vibration frequency of the vibrating wires is changed. The electromagnetic coil excites the vibrating wire and measures the vibration frequency, the frequency signal is transmitted to the reading device through the cable, and the strain quantity in the measured structure can be measured.

In the prior art, strain gauges are used for measuring tiny strain of a structure so as to monitor and evaluate deformation conditions of the structure, in order to obtain accurate measurement results, the strain gauges should be accurately installed at key positions of the structure, if incorrect strain gauge installation possibly causes failure in detecting actual deformation of the structure, potential structural potential hazards are ignored, therefore, strain gauge installation steps are generally strict, the installation flow of the strain gauges is more, currently, when personnel upload strain gauge installation data, only all the installation steps of the strain gauges can be packaged and uploaded, and data storage is disordered, for example, all the installation steps of grinding, welding points, waterproof compound coating and the like of welding substrates in the strain gauges are directly and integrally uploaded, inspection time is increased when installation data verification is carried out at a later stage, and the risk of operation steps is present.

Therefore, how to upload corresponding installation data according to the specific installation steps of the twin space and the strain gauge avoids forgetting the operation steps of the installer, and can realize layered viewing of different operation steps at the same part at the same time, so that the problem to be solved is urgent.

Disclosure of Invention

The embodiment of the invention provides a processing method and a processing system for a vibrating wire type spot welding strain gauge, which are used for uploading corresponding installation data according to a twin space and a strain gauge specific installation step, avoiding forgetting of the operation steps of an installer, and realizing layered viewing of different operation steps at the same part.

In a first aspect of an embodiment of the present invention, a processing method for a vibrating wire spot welding strain gauge is provided, including:

The method comprises the steps of calling a bridge twin space corresponding to a target bridge, receiving configuration information of configuration of the bridge twin space by a management end, and updating the bridge twin space based on a strain gauge module and the configuration information to obtain an indication twin space;

Based on the triggering operation of the installing end on the strain gauge module in the indication twin space, a decomposition module corresponding to the assembly form of the strain gauge module is called for display, and the decomposition module comprises a plurality of sub-model units positioned at decomposition positions;

According to the uploading operation of the installation end to the sub-model unit, a form switching strategy is called to update the models of the corresponding decomposition module and the strain gauge module, and a verification twin space is obtained;

And verifying the installation data corresponding to the sub-model units based on a customized verification strategy to obtain detection data, updating the strain gauge modules in the verification twin space according to the detection data to obtain a display twin space, and sending the display twin space to a management end.

Optionally, in one possible implementation manner of the first aspect, the receiving the configuration information of the configuration of the bridge twin space by the management end, updating the bridge twin space based on the strain gauge module and the configuration information to obtain the indicated twin space includes:

Receiving configuration information of the bridge twin space configuration by a management end, and analyzing the configuration information to obtain setting positions corresponding to the strain gauge modules;

And updating the strain gauge module into the bridge twin space based on the setting position to obtain an indication twin space.

Optionally, in one possible implementation manner of the first aspect, the invoking the form switching policy to update the model of the corresponding decomposition module and the strain gauge module according to the uploading operation of the installation end on the sub-model unit to obtain the verification twin space includes:

And updating the sub-model unit positioned at the decomposition position in the decomposition module to the combination position of the strain gauge module when the installation end uploads the installation data corresponding to the sub-model unit according to the uploading operation of the installation end on the sub-model unit, and repeating the steps until the decomposition module does not have the sub-model unit, so as to obtain a verification twin space.

Optionally, in one possible implementation manner of the first aspect, when the determining that the installation end uploads the installation data corresponding to the sub-model unit according to the uploading operation of the installation end on the sub-model unit, updating the sub-model unit located at the decomposition position in the decomposition module to the combination position of the strain gauge module, and repeating the above steps until the decomposition module does not have the sub-model unit, to obtain the verification twin space, where the step includes:

based on the model types of the plurality of sub-model units positioned at the decomposition positions, taking a plurality of sub-model units of the same model type as a linkage unit, and acquiring the combined positions of the linkage unit in the strain gauge module;

according to the uploading operation of the installation end on the sub-model units of the decomposition position, taking the linkage units corresponding to the corresponding sub-model units as uploading units;

When the installation end is determined to upload the installation data corresponding to the uploading unit, updating the uploading unit of the decomposition position to the combination position, and repeating the steps until the decomposition module does not have a submodel unit, so as to obtain a verification twin space.

Optionally, in one possible implementation manner of the first aspect, the verifying the installation data corresponding to the sub-model unit based on the customized verification policy to obtain the detection data includes:

Obtaining detection attributes of the sub-model units, wherein the detection attributes comprise automatic detection attributes and manual detection attributes;

Invoking a preset welding spot pixel value based on the automatic detection attribute, and verifying the installation data of the corresponding linkage unit of the corresponding sub-model unit according to the preset welding spot pixel value to obtain detection data;

Based on the manual detection attribute, the receiving management end performs verification operation on the strain gauge module in the verification twin space, and verifies the installation data corresponding to the sub-model unit according to the verification operation to obtain detection data.

Optionally, in one possible implementation manner of the first aspect, the retrieving a preset welding spot pixel value based on the automatic detection attribute, verifying, according to the preset welding spot pixel value, installation data of a corresponding linkage unit of the corresponding sub-model unit to obtain detection data includes:

extracting a preset welding spot pixel value based on the automatic detection attribute, and extracting a welding spot pixel point in the installation data of the corresponding linkage unit according to the preset welding spot pixel value;

counting the adjacent welding spot pixel points to obtain a plurality of welding spot pixel point sets, and obtaining the number of the welding spot pixel point sets as the number of mounting welding spots;

and obtaining detection data according to the comparison information of the number of the mounting welding spots and the preset number.

Optionally, in one possible implementation manner of the first aspect, the verifying operation of the strain gauge module in the verification twin space by the receiving management end based on the manual detection attribute, verifying the installation data corresponding to the sub-model unit according to the verifying operation to obtain detection data includes:

Based on the manual detection attribute, receiving verification operation of the management end on the strain gauge module in the verification twin space, and according to trigger information of the management end on the corresponding sub-model unit in the decomposition module, retrieving installation data corresponding to the corresponding sub-model unit and sending the installation data to the management end;

and receiving a verification result of the management terminal on the corresponding installation data as detection data.

Optionally, in one possible implementation manner of the first aspect, the updating, by the detection data, the strain gauge module in the verification twin space, and sending the obtained exhibition twin space to a management end includes:

And determining the detection data as abnormal data, calling a preset abnormal pixel value, updating the pixel value of the strain gauge module in the verification twin space according to the preset abnormal pixel value, obtaining a display twin space, and sending the display twin space to a management end.

Optionally, in a possible implementation manner of the first aspect, before the step of updating the bridge twin space based on the strain gauge module and the configuration information to obtain the indicated twin space, the method further includes:

acquiring each sub-bridge module in the bridge twinning space, wherein the sub-bridge modules have corresponding preset rotation directions and preset rotation angles;

According to the sub-bridge module, a preset rotation direction and a preset rotation angle corresponding to the sub-bridge module are adjusted, a center point of a preset positioning frame is obtained to serve as an active positioning point, and the active positioning point is aligned with the setting position;

and carrying out angle adjustment on the preset positioning frame according to the preset rotation direction and the preset rotation angle based on the active positioning point to obtain an adjusted angle positioning frame.

In a second aspect of embodiments of the present invention, there is provided a processing system for a vibrating wire spot welding strain gauge, comprising:

The receiving module is used for invoking a bridge twinning space corresponding to the target bridge, receiving configuration information of the bridge twinning space configuration by the management end, and updating the bridge twinning space based on the strain gauge module and the configuration information to obtain an indication twinning space;

The triggering module is used for calling a decomposition module corresponding to the assembly form of the strain gauge module to display based on the triggering operation of the strain gauge module in the indication twin space by the installation end, and the decomposition module comprises a plurality of sub-model units positioned at decomposition positions;

The updating module is used for calling a form switching strategy to update the models of the corresponding decomposition module and the strain gauge module according to the uploading operation of the installation end on the sub-model unit, so as to obtain a verification twin space;

The verification module is used for verifying the installation data corresponding to the sub-model units based on the customized verification strategy to obtain detection data, updating the strain gauge module in the verification twin space according to the detection data to obtain a display twin space, and sending the display twin space to the management end.

In a third aspect of an embodiment of the present invention, there is provided an electronic device including: a memory, a processor and a computer program stored in the memory, the processor running the computer program to perform the first aspect of the invention and the methods that the first aspect may relate to.

In a fourth aspect of embodiments of the present invention, there is provided a storage medium having stored therein a computer program for implementing the method of the first aspect and the various possible aspects of the first aspect when executed by a processor.

The beneficial effects of the invention are as follows:

1. According to the invention, the strainometer module is displayed by using the twin space, each target object in the strainometer module is decomposed to upload corresponding operation installation data, layered checking of different operation steps at the same part is realized, the checking efficiency of the management end on the installation operation is improved, and meanwhile, the forgetting of the operation steps of an installer can be avoided. Firstly, the bridge twin space is updated through the strain gauge module and the acquired configuration information to obtain the indicated twin space. According to the method, the installation data of different operation steps of the same module are uploaded step by step through the plurality of sub-model units, follow-up layered viewing is guaranteed, the analysis module and the strain gauge module are subjected to model updating according to a form switching strategy through uploading operation of the sub-model units of the installation end, a verification twin space is obtained, the sub-model units of the analysis module are subjected to one-to-one correspondence updating through the form switching strategy, reminding of the installation operation steps is achieved in the process of model updating, missing of the installation steps is avoided, finally, the installation data corresponding to the sub-model units are verified to obtain detection data, and the obtained display twin space is further updated according to the verification data, so that the management end timely overhauls related abnormal operations according to the display twin space.

2. According to the method, the uploaded installation data are in one-to-one correspondence with the target objects obtained in the installation step, and the form switching strategy is used for enabling the sub-model units in the decomposition module to be in one-to-one correspondence for updating, so that layered checking of the installation data is realized, and meanwhile, in the process of updating the model, reminding of the installation operation step is realized, and the missing of the installation step is avoided. Firstly, the configuration information of bridge twinning space configuration is analyzed to obtain the corresponding setting position of each strain gauge, then the strain gauge module is updated to the corresponding setting position in the bridge twinning space to obtain the indicated twinning space, secondly, the sub-model units positioned at the decomposition position in the decomposition module are updated to the combination position of the strain gauge module, wherein a plurality of sub-model units of the same model type in the sub-model units positioned at the decomposition position are taken as linkage units, meanwhile, the combination position of the linkage units in the strain gauge module is obtained, furthermore, the linkage units with uploading operation are taken as uploading units, therefore, when the installation data corresponding to the uploading units are uploaded at the installation end, the uploading units are updated to the combination position, when the sub-model units are not arranged at the decomposition position in the decomposition module, the verification twinning space is obtained, the obtained verification twinning space enables the management end to be checked in a layered mode, the installation data of overlapping operation steps which can be clearly checked at the same position are realized, and the follow-up detection data can be conveniently obtained.

3. According to the invention, automatic detection or manual detection can be performed through the detection attribute of the sub-model unit, detection data can be rapidly obtained through classification detection, when abnormal detection data appear, the verification twin space is updated to obtain the display twin space, so that a management end can intuitively check the operation step of installing the strain gauge abnormally through the display twin space, overhaul the strain gauge in time according to an abnormal result, and overhaul efficiency is improved.

Drawings

FIG. 1 is a flow chart of a process for a vibrating wire spot welding strain gauge provided by the present invention;

FIG. 2 is a schematic diagram of a processing system for a vibrating wire spot welding strain gauge according to the present invention;

fig. 3 is a schematic hardware structure of an electronic device according to the present invention.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The terms "first," "second," "third," "fourth" and the like in the description and in the claims and in the above drawings, if any, are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that the embodiments of the invention described herein may be implemented in sequences other than those illustrated or otherwise described herein.

It should be understood that, in various embodiments of the present invention, the sequence number of each process does not mean that the execution sequence of each process should be determined by its functions and internal logic, and should not constitute any limitation on the implementation process of the embodiments of the present invention.

It should be understood that in the present invention, "comprising" and "having" and any variations thereof are intended to cover non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements that are expressly listed or inherent to such process, method, article, or apparatus.

It should be understood that in the present invention, "plurality" means two or more. "and/or" is merely an association relationship describing an association object, meaning that there may be three relationships, e.g., a and/or B, may represent: a exists alone, A and B exist together, and B exists alone. The character "/" generally indicates that the context-dependent object is an "or" relationship. "comprising A, B and C", "comprising A, B, C" means that all three of A, B, C are comprised, "comprising A, B or C" means that one of A, B, C is comprised, "comprising A, B and/or C" means that any 1 or any 2 or 3 of A, B, C are comprised.

It should be understood that in the present invention, "B corresponding to a", "a corresponding to B", or "B corresponding to a" means that B is associated with a, from which B can be determined. Determining B from a does not mean determining B from a alone, but may also determine B from a and/or other information. The matching of A and B is that the similarity of A and B is larger than or equal to a preset threshold value.

As used herein, the term "if" may be interpreted as "at … …" or "at … …" or "in response to a determination" or "in response to a detection", depending on the context.

The invention provides a processing method for a vibrating wire type spot welding strain gauge, which is shown in fig. 1 and comprises the following steps of S1-S4:

S1, a bridge twin space corresponding to a target bridge is called, configuration information of the bridge twin space configuration is received by a management end, and the bridge twin space is updated based on a strain gauge module and the configuration information to obtain an indication twin space.

It should be noted that, in order to facilitate the transmission and viewing of relevant information, a corresponding bridge twinning space is generated according to the real bridge.

It can be understood that the configuration information of the configuration of the bridge twinning space by the management end is received in the bridge twinning space corresponding to the target bridge, and the strain gauge module is configured at the corresponding position of the bridge twinning space according to the configuration information, so that the indication twinning space is updated.

The bridge twinning space is a bridge twinning space.

According to the embodiment, the configuration of the strain gauge module is completed in the bridge twinning space according to the configuration information, the indication twinning space is updated, and the space position is provided for uploading and verifying the follow-up installation data.

In some embodiments, the step S1 (the receiving management end updates the configuration information of the bridge twin space based on the strain gauge module and the configuration information to obtain the indicated twin space) includes steps S11-S12:

S11, receiving configuration information of the bridge twinning space configuration by the management end, and analyzing the configuration information to obtain setting positions corresponding to the strain gauge modules.

It should be noted that, a plurality of strain gauges are installed on the bridge, and the installation positions of the strain gauges are different, so that corresponding configuration information is configured in the corresponding bridge twinning space.

It is easy to understand that the configuration information of the management end on the configuration of the bridge twin space is received, and the configuration information is decomposed to obtain the setting positions corresponding to the strain gauge modules.

The setting position is a configuration position of the strain gauge module in the bridge twinning space, and may be a three-dimensional coordinate in the twinning space, or may be a positioning frame for setting the strain gauge module, for example, a rectangular frame, or even a corresponding setting position obtained by manually and actively triggering the bridge twinning space, which is not limited herein, so that the strain gauge module can be directly set through the configuration position in the following process, which is not described herein.

And S12, updating the strain gauge module into the bridge twinning space based on the setting position to obtain an indication twinning space.

It is easy to understand that the management end can actively trigger the corresponding position of the bridge twinning space, so as to obtain the set position.

It can be understood that the strain gauge module is updated to the bridge twin space by the resolved setting position, and the updated bridge twin space is used as the indication twin space.

S2, based on triggering operation of the installing end on the strain gauge module in the indication twin space, a decomposition module corresponding to the assembly form of the strain gauge module is called for display, and the decomposition module comprises a plurality of sub-model units positioned at decomposition positions.

It should be noted that, when installing the strain gauge module, there are multiple installation operations at the same position, for example, when the strain gauge installs the welding substrate, there are welding points first, then waterproof compound agent is coated at the welding points to form a waterproof coating, and an adhesive, etc., but in the prior art, the corresponding transmission of the installation data of the components corresponding to different steps cannot be realized, because different operation steps at the same part overlap, for example, the welding points overlap with the waterproof coating, and in the prior art, the uploaded data, for example, the operation steps of the welding points and the waterproof coating, cannot be distinguished, so that when the installer needs to upload relevant data of different operations at the installation end, a corresponding decomposition module can be generated.

It can be understood that the assembly form of the strain gauge module is taken out and displayed by the triggering operation of the mounting end corresponding to the strain gauge module in the indication twin space, wherein the assembly form comprises a plurality of sub-model units positioned at the assembly position.

The decomposition module can be a module formed by the strain gauges corresponding to the explosion diagrams, and the decomposition module is a module for explosion display of each sub-model unit in the strain gauge module according to the installation flow.

It should be noted that after the installation end triggers the strain gauge module in the indication twin space, the strain gauge module at the original position is displayed above by the decomposition module in the assembly form, which can be understood that the strain gauge module is displayed in the form of an explosion diagram, and the explosion diagram is split into a plurality of sub-model units according to the installation flow of the strain gauge module.

The assembly form is the form of each object in the strain gauge module, for example, a welding substrate, an end seat, a protection tube, and the like, for example, the objects such as the mounting substrate, the welding substrate, and the like are sequentially displayed according to a mounting process from bottom to top, so that each sub-model unit has a corresponding position, the position is a decomposition position, the decomposition position is a position set for each sub-model unit according to the strain gauge mounting step, it can be understood that the position of each component in the explosion diagram is the position of each sub-model unit, for example, the object can be the object obtained after the mounting operation included in the same component position in the strain gauge module, for example, the object can be a welding substrate, a welding point, a waterproof coating formed by a waterproof complexing agent, and the like, that is, the welding point corresponds to one sub-model unit, the waterproof complexing agent corresponds to one sub-model unit, and the welding substrate corresponds to one sub-model unit. Through the decomposition module that transfers out, be convenient for follow-up personnel trigger and upload the installation data that each operation corresponds in overlapping portion, also avoid the installer to miss the operation step simultaneously.

And S3, according to the uploading operation of the installation end to the submodel unit, a form switching strategy is called to update the model of the corresponding decomposition module and strain gauge module, and a verification twin space is obtained.

It should be noted that, when the trigger operation shows the decomposition module, the corresponding strain gauge module in the twin space is indicated to disappear, and meanwhile, the sub-model unit of the decomposition module is shown at the decomposition position, and when the sub-model unit is uploaded, the corresponding decomposition module and the strain gauge module are updated.

It can be understood that when the installation end performs uploading operation on the sub-model unit, the morphology switching strategy is called to update the model of the corresponding decomposition module and the strain gauge module, and the verification twin space is obtained after updating.

And the obtained verification twin space is convenient for subsequent verification and verification of related data, and timely verification is realized when abnormality occurs.

In some embodiments, the step S3 (the step S31 of updating the model of the corresponding decomposition module and the strain gauge module according to the uploading operation of the installation end to the sub-model unit and invoking the form switching policy to obtain the verification twin space) includes:

And S31, when the installation end uploads the installation data corresponding to the sub-model units according to the uploading operation of the installation end on the sub-model units, updating the sub-model units positioned at the decomposition position in the decomposition module to the combination position of the strain gauge module, and repeating the steps until the decomposition module does not have the sub-model units, so as to obtain the verification twin space.

It can be understood that when the installation end performs the uploading operation on the sub-model unit and determines that the installation data uploaded by the installation end corresponds to the sub-model unit, updating the sub-model unit located at the decomposition position in the decomposition module to the combination position of the strain gauge module, and repeating the above steps until the decomposition module does not have the sub-model unit, thereby obtaining the verification twin space.

The installation data are corresponding to the submodel units, and can be videos or pictures, for example, videos of polishing the welding substrate, videos or pictures of finishing the welding point, and verification of the twin space is to indicate that the twin space is updated to be the twin space containing the installation data.

Through the embodiment, the verification twin space containing the installation data is obtained, so that each operation step can be detected in a targeted manner.

In some embodiments, in step S31 (when the installation end determines that the installation end uploads the installation data corresponding to the sub-model unit according to the upload operation of the installation end on the sub-model unit, the sub-model unit located at the decomposition position in the decomposition module is updated to the combination position of the strain gauge module, and the above steps are repeated until the decomposition module does not have the sub-model unit, so as to obtain the verification twin space) includes steps S311-S313:

S311, based on the model types of the plurality of sub-model units positioned at the decomposition positions, taking the plurality of sub-model units of the same model type as a linkage unit, and acquiring the combined positions of the linkage unit in the strain gauge module.

In practical application, when the installation data of the welding spots are uploaded, the installation data comprise the number of installation processes of all the welding spots, namely all the welding spot data are uploaded, and each welding spot is not uploaded one by one, so that a plurality of sub-model units of the same model type are used as linkage units.

It will be appreciated that the strain gage has two bond pads and each bond pad has a plurality of bond pads, and therefore the sub-model elements corresponding to the plurality of bond pads are of the same model type.

It is understood that, depending on the model types of the plurality of sub-model units located at the decomposition positions, a plurality of sub-model units of the same model type are used as the linkage units, and the combined positions of the linkage units in the strain gauge module are acquired at the same time.

The combined position is the position of the linkage unit in the strain gauge module.

For example: and taking the submodel units corresponding to the welding points as a linkage unit, and simultaneously acquiring the positions of the welding points on the welding substrate.

According to the method and the device for uploading the installation data, the linkage unit is determined according to the embodiment, the operation of uploading the installation data to the plurality of sub-model units of the same model type is performed according to the actual situation, the efficiency of uploading the installation data by an installer is improved, and the corresponding installation data can be conveniently checked by subsequent personnel.

S312, according to the uploading operation of the installation end on the sub-model units of the decomposition position, the linkage units corresponding to the sub-model units are used as uploading units.

It can be understood that when the installation end obtains the sub-model unit of the analysis position to perform the uploading operation step, the linkage unit corresponding to the corresponding sub-model unit is used as the uploading unit.

For example: when the sub-model units corresponding to the welding substrates at the decomposition positions are clicked to carry out the installation data uploading operation, the linkage units corresponding to the two sub-model units corresponding to the two welding substrates are used as uploading units, and when the sub-model units corresponding to the welding points at the decomposition positions are clicked to carry out the installation data uploading operation, the linkage units corresponding to the sub-model units corresponding to the welding points are used as uploading units.

S313, when the installation end is determined to upload the installation data corresponding to the uploading unit, updating the uploading unit of the decomposition position to the combination position, and repeating the steps until the decomposition module does not have a submodel unit, so as to obtain a verification twin space.

Since the decomposition module includes a plurality of linkage units, when the linkage units are uploaded with installation data and the positions are updated, the linkage units are uploaded and the positions are updated in a one-to-one correspondence.

It can be understood that when the installation end is determined to upload the installation data corresponding to the uploading unit, the uploading unit of the decomposition position is updated to the combined position, and the steps of uploading and position updating are repeated until the decomposition position corresponding to the decomposition module does not have the sub-model unit, so that the verification twin space is obtained.

For example: when the linkage unit corresponding to the first part of welding substrate is clicked to upload the installation data of the polishing substrate, the linkage unit corresponding to the welding substrate at the decomposition position disappears, and meanwhile, after the linkage unit of the welding substrate is updated at the combination position corresponding to the strain gauge module, the linkage unit corresponding to the second part of welding point is clicked to upload the installation data of the welding point, the linkage unit corresponding to the welding point at the decomposition position disappears, and after the linkage unit corresponding to the welding point is updated at the combination position, subsequent uploading and updating are carried out until all the linkage units are updated at the corresponding combination position, and at the moment, the verification twin space is obtained.

It is to be understood that the invention sequentially uploads the corresponding installation data according to each sub-model unit in the decomposition module, updates the sub-model unit to the combined position in the original strain gauge module after the installation data of the corresponding sub-model unit is uploaded, for example, displays an explosion diagram of the strain gauge, wherein the explosion diagram is provided with a substrate, a welding spot and the like, a user triggers the substrate in the explosion diagram and receives the installation data of the corresponding polished substrate to bind with the substrate, after binding, the substrate in the explosion diagram disappears and updates to the position of the substrate in the original strain gauge, and then one-by-one binding update is carried out, thereby obtaining the verification twin space.

According to the embodiment, in the prior art, as different operation steps at the same part of the strain gauge are overlapped, a user cannot determine an object of uploaded installation data, for example, a welding spot and a step of preventing the welding spot from being oxidized and smeared with a waterproof complexing agent to form a waterproof coating when uploading, and the user cannot determine whether the uploaded data is the installation data of the welding spot or the installation flow of smeared with the waterproof complexing agent when triggering the welding spot.

And S4, verifying the installation data corresponding to the sub-model units based on a customized verification strategy to obtain detection data, updating the strain gauge module in the verification twin space according to the detection data to obtain a display twin space, and sending the display twin space to a management end.

It should be noted that, the installation of the strain gauge is strict, for example, the polishing degree of the welding substrate, the number of welding points and the like have corresponding configuration requirements, so that in order to prevent the installation operation of an installer from generating errors, for example, the number of the welding points is insufficient, the corresponding uploading installation data of the sub-model unit can be verified.

It can be understood that the installation data corresponding to the sub-model unit is verified according to the customized verification policy to obtain detection data, the strain gauge module in the verification twin space is updated through the detection data to obtain a display twin space, and the display twin space is sent to the management end.

The detection data is the result data of verifying the installation data, and may be normal or abnormal, for example.

Through the embodiment, the detection data can be obtained, the strain gauge module in the verification twin space is updated according to the detection data, and meanwhile, the obtained display twin space is sent to the management end, so that related personnel obtain the installation effect through the display twin space, and when abnormality occurs, maintenance and change can be timely carried out.

In some embodiments, the step S4 (the verification of the installation data corresponding to the sub-model unit based on the customized verification policy to obtain the detection data) includes steps S41-S43:

S41, obtaining detection attributes of the sub-model units, wherein the detection attributes comprise automatic detection attributes and manual detection attributes.

It should be noted that, when verifying the uploaded installation data, because the attribute of some sub-model units is relatively special, for example, when verifying the installation data corresponding to the waterproof complexing agent, in order to ensure that the used article is correct, the installation data needs to be detected manually and autonomously, so that the detection attribute classification can be performed on the sub-model units.

It is understood that the detection attributes of the sub-model units are obtained, and the detection attributes include automatic detection attributes and manual detection attributes.

Wherein, the automatic detection attribute is preset by human, and the manual detection attribute is preset by human, and will not be described here.

For example: the detection attribute of the sub-model unit corresponding to the welding point can be an automatic detection attribute.

S42, invoking a preset welding spot pixel value based on the automatic detection attribute, and verifying the installation data of the corresponding linkage unit of the corresponding sub-model unit according to the preset welding spot pixel value to obtain detection data.

It can be understood that the preset welding spot pixel value is obtained according to the automatic detection attribute, and the installation data of the corresponding linkage unit of the corresponding sub-model unit is verified through the preset welding spot pixel value to obtain detection data.

The preset welding point pixel value is a preset welding point pixel value, and can be silver.

In some embodiments, the step S42 (the step of retrieving a preset solder joint pixel value based on the automatic detection attribute, and verifying the installation data of the corresponding linkage unit of the corresponding sub-model unit according to the preset solder joint pixel value to obtain the detection data) includes steps S421 to S423:

S421, a preset welding spot pixel value is called based on the automatic detection attribute, and welding spot pixel points in the installation data of the corresponding linkage unit are extracted according to the preset welding spot pixel value.

It can be understood that the preset welding spot pixel value is adjusted through the automatic detection attribute, and the welding spot pixel point in the installation data of the corresponding linkage unit is extracted according to the preset welding spot pixel value.

The welding spot pixel points are image pixel points of the welding spots.

For example: after the welding point is finished, an installer shoots a picture after finishing installation and uploads the picture to a corresponding linkage unit from the installation end, and then the server compares and extracts each pixel value in the uploaded welding point picture according to the preset welding point pixel value silver, and extracts the welding point pixel point of the silver welding point in the picture after comparison.

S422, counting the adjacent welding spot pixel points to obtain a plurality of welding spot pixel point sets, and obtaining the number of the welding spot pixel point sets as the number of the mounting welding spots.

It should be noted that, a large number of welding spot pixels can be extracted from the installation data, and each pixel has a corresponding position, so that in order to obtain the number of the installation welding spots, the number of the welding spot pixel sets can be obtained by counting the adjacent welding spot pixels, and the number of the installed welding spots is further obtained.

It can be understood that a plurality of welding spot pixel point sets can be obtained by counting adjacent welding spot pixel points, and the number of the counted welding spot pixel point sets is taken as the number of the mounting welding spots.

The welding spot pixel point set is a set of adjacent welding spot pixel points.

For example: and counting adjacent welding spot pixel points in the welding spot pixel points extracted from the picture corresponding to the linkage unit of the welding spot to be used as a set, and obtaining 10 welding spot pixel point sets, wherein the number of the mounting welding spots is 10.

S423, obtaining detection data according to the comparison information of the number of the mounting welding spots and the preset number.

It can be understood that the detection data is obtained according to the comparison information by comparing the number of the mounting pads with the preset number.

The preset number is the number of welding points required to be installed, which is manually preset.

For example: when the preset number is 10, comparing the number 10 of the mounting welding spots with the preset number 10 to obtain consistent detection data, and when the number 6 of the mounting welding spots is compared with the preset number 10, obtaining abnormal detection data.

Through the implementation mode, the detection data is obtained to finish verification, and a detection result is provided for a subsequent sending management end.

S43, based on the manual detection attribute, receiving verification operation of the management end on the strain gauge module in the verification twin space, and verifying the installation data corresponding to the sub-model unit according to the verification operation to obtain detection data.

It can be understood that, when the sub-model unit corresponds to the manual detection attribute, the server receives the verification operation of the management end on verifying the strain gauge module in the twin space, and obtains the detection data by verifying the installation data corresponding to the sub-model unit.

In some embodiments, the step S43 (the step S431-S432 of verifying the installation data corresponding to the sub-model unit according to the verification operation by the receiving management end for verifying the verification operation of the strain gauge module in the verification twin space based on the manual detection attribute) includes the steps of:

S431, based on the manual detection attribute, receiving verification operation of the management end on the strain gauge module in the verification twin space, and according to trigger information of the management end on the corresponding sub-model unit in the decomposition module, retrieving installation data corresponding to the corresponding sub-model unit and sending the installation data to the management end.

Besides the welding spots, since the waterproof coating, the adhesive and the like are generally transparent liquids, automatic identification is difficult, and thus, the correctness and the integrity of the installation process are ensured by checking corresponding installation data by personnel.

It can be understood that the verification operation of the management end on the strain gauge module in the verification twin space can be correspondingly received according to the manual detection attribute, and the installation data corresponding to the corresponding sub-model units are called according to the triggering information of the management end on the corresponding sub-model units in the decomposition module and sent to the management end.

Specifically, according to the triggering information of the corresponding sub-model units in the analysis module by the management end, the installation data corresponding to the corresponding sub-model units are called and sent to the management end for checking.

For example: and receiving verification results of the management end on the installation data of waterproof complexing agent, adhesive and the like in the strain gauge module in the twinning space, such as a welding substrate, the waterproof complexing agent and the like, and sending the installation data of the corresponding sub-model unit to the management end.

Through the embodiment, the invention can call out the installation data of the corresponding sub-model unit and send the installation data to the management end for manual verification so as to perform manual detection according to the installation data.

S432, receiving a verification result of the management end on the corresponding installation data as detection data.

It can be understood that, after the management end verifies, the server will receive the verification result of the management end on the corresponding installation data, and at the same time, the obtained verification result is used as the detection data.

For example: when the normal verification result is obtained after the manual detection, the verification result is taken as detection data normally, and when the abnormal verification result is obtained after the manual detection, the verification result is taken as detection data abnormally, and it is easy to understand that the detection data can be normal or abnormal.

In some embodiments, the step S4 (the detection data updates the strain gauge module in the verification twin space, and the obtained exhibition twin space is sent to the management end) includes step S44:

S44, determining the detection data as abnormal data, calling a preset abnormal pixel value, updating the pixel value of the strain gauge module in the verification twin space according to the preset abnormal pixel value, obtaining a display twin space and sending the display twin space to a management end.

It will be appreciated that the strain gage module is an abnormal strain gage module, whether it is a solder joint abnormality or other step abnormality.

It can be understood that when the detected data is abnormal data, a preset abnormal pixel value is called, and meanwhile, the pixel value of the strain gauge module in the verification twin space is updated according to the preset abnormal pixel value, so that a display twin space is obtained, and the display twin space is sent to the management end.

The preset abnormal pixel value is an image pixel value corresponding to an abnormal result preset manually, and may be red, yellow, etc.

For example: when the detection data corresponding to the welding substrate is abnormal data, calling out a preset abnormal pixel value red, updating the red pixel value of the strain gauge module in the verification twin space, obtaining a display twin space after updating, and sending the display twin space corresponding to the strain gauge module marked red to the management end.

It should be noted that, the setting position in step S11 may obtain the configuration information according to the actual investigation through the coordinate position, and determine the setting position, and in addition, the present invention may also obtain the setting position corresponding to the strain gauge module through the position determination performed by the positioning frame.

In some embodiments, the step of step S1 (before the step of updating the bridge twin space based on the strain gauge module and the configuration information to obtain the indicated twin space) further comprises steps a11-a14:

A11, receiving configuration information of the bridge twin space configuration by the management end, and analyzing the configuration information to obtain setting positions corresponding to the strain gauge modules.

Since a plurality of steel structures, such as bridges and piles, are provided on the bridge, a plurality of strain gauges are required to be installed for data measurement, and the installation positions are different from each other, so that corresponding configuration information is configured in the corresponding bridge twinning space.

The setting position is a position where the strain gauge module is set, for example, a three-dimensional coordinate in the twin space.

A12, obtaining each sub-bridge module in the bridge twinning space, wherein the sub-bridge modules have corresponding preset rotation directions and preset rotation angles.

Since the positions of the steel structures on the bridge are different, each sub-bridge module has a different arrangement position in the bridge twinning space.

It can be understood that each sub-bridge module in the bridge twinning space has a corresponding preset rotation direction and preset rotation angle.

The preset rotation direction is the rotation direction of the manual preset adjusting strain gauge module, and the preset rotation angle is the rotation angle of the manual preset adjusting strain gauge module.

A13, according to the sub-bridge module, the corresponding preset rotation direction and preset rotation angle are called, the center point of the preset positioning frame is obtained to serve as an active positioning point, and the active positioning point is aligned with the setting position.

It can be understood that the preset rotation direction and the preset rotation angle corresponding to the sub-bridge module are called, the center point of the preset positioning frame is obtained, the center point of the preset positioning frame is used as an active positioning point, and the active positioning point is aligned with the setting position.

The preset positioning frame is a preset positioning frame.

It is easy to understand that the positioning frame configured in advance can be used for storing the strain gauge, and meanwhile, the obtained central point of the preset positioning frame is used as an active positioning point to be automatically aligned with the setting position, so that the strain gauge module can be positioned at an accurate storage position in the bridge twinning space.

A14, carrying out angle adjustment on the preset positioning frame according to the preset rotation direction and the preset rotation angle based on the active positioning point, and obtaining an adjusted angle positioning frame.

It can be understood that the preset positioning frame is subjected to angle adjustment according to the preset rotation direction and the preset rotation angle of the active positioning point, so as to obtain the adjusted angle positioning frame.

The angle positioning frame is a positioning frame with a preset positioning frame adjusted.

For example: the preset positioning frame is positioned at the set position through the active positioning point, but the positioning frame is in a horizontal state and has obvious deviation from the actual installation direction, so that the active positioning point of the preset positioning frame is unchanged, the preset positioning frame is rotated by 120 degrees in the anticlockwise rotation direction, and the angle positioning frame is obtained after adjustment.

It is to be added that, because the construction of the target bridge is numerous and complex, the strain timing is configured, and under the condition that the position of the strain gauge is complex, the positioning frame can be actively adjusted according to the preset rotation direction and the preset rotation angle which are actively set in advance by people, wherein when the configured environment is simpler and the preset rotation direction and the preset rotation angle are not configured, the system can acquire related data to automatically configure and adjust the positioning frame.

Thus, in some embodiments, step S1 further includes steps B11-B14:

And B11, determining that the corresponding sub-bridge module does not have a corresponding preset rotation direction and preset rotation angle, and taking the corresponding sub-bridge module as an automatic adjusting module.

It can be appreciated that when it is determined that the corresponding sub-bridge module does not have the corresponding preset rotation direction and preset rotation angle, the corresponding sub-bridge module serves as an automatic adjustment module.

And B12, acquiring a center point of the corresponding preset positioning frame at the automatic adjusting module as an automatic positioning point, and establishing a coordinate system based on the automatic positioning point as an origin.

It can be understood that the center point of the corresponding preset positioning frame at the automatic adjusting module is obtained, the center point of the corresponding preset positioning frame is used as an automatic positioning point, and a coordinate system is established according to the automatic positioning point as an origin.

For example: when the steel structure body of the suspended bridge is determined to be an automatic adjusting module, a central point of a corresponding preset positioning frame at the automatic adjusting module is obtained and is used as an automatic positioning point, and a coordinate system is established by taking the automatic positioning point as an origin.

Through the implementation mode, the invention is convenient for the generation of the subsequent center line and the adjustment of the preset positioning frame through the constructed coordinate system.

And B13, acquiring center points of two faces in the width direction of the automatic adjusting module, and connecting the center points to obtain a center line consistent with the direction of the automatic adjusting module.

In the middle of the bridge twinning, the automatic adjusting module is in a three-dimensional shape consistent with the actual installation target, so that the center points of two surfaces in the three-dimensional automatic adjusting module can be obtained, and a center line is obtained.

It is understood that the center points of the two faces in the width direction of the automatic adjustment module are obtained, and the center points are connected to obtain the center line in accordance with the direction of the automatic adjustment module.

And B14, determining the inclination angle of the central line in the coordinate system, and carrying out angle adjustment on the preset positioning frame based on the automatic positioning point in the inclination angle and the anticlockwise direction to obtain an adjusted angle positioning frame.

It can be understood that the inclination angle of the central line in the coordinate system is determined according to the established coordinate system and the obtained central line, and the preset positioning frame is subjected to angle adjustment according to the automatic positioning point in the inclination angle and the anticlockwise direction, so that the adjusted angle positioning frame is obtained.

The inclination angle is the angle difference between the center line and the plane preset positioning frame.

Through the embodiment, the angle positioning frame is obtained, so that the accurate installation position of the strain gauge module can be conveniently determined later.

Referring to fig. 2, a schematic structural diagram of a processing system for a vibrating wire spot welding strain gauge according to an embodiment of the present invention is shown, where the system includes:

The receiving module is used for invoking the bridge twinning space corresponding to the target bridge, receiving configuration information of the bridge twinning space configuration by the management end, and updating the bridge twinning space based on the strain gauge module and the configuration information to obtain the indicated twinning space.

The triggering module is used for calling and displaying a decomposition module corresponding to the assembly form of the strain gauge module based on the triggering operation of the mounting end on the strain gauge module in the indication twin space, and the decomposition module comprises a plurality of sub-model units positioned at the decomposition position.

And the updating module is used for calling a form switching strategy to update the model of the corresponding decomposition module and the strain gauge module according to the uploading operation of the installation end on the sub-model unit, so as to obtain a verification twin space.

As shown in fig. 3, a schematic hardware structure of an electronic device according to an embodiment of the present invention is shown, where the electronic device 30 includes: a processor 31, a memory 32 and a computer program; wherein the method comprises the steps of

A memory 32 for storing said computer program, which memory may also be a flash memory (flash). Such as application programs, functional modules, etc. implementing the methods described above.

A processor 31 for executing the computer program stored in the memory to implement the steps executed by the apparatus in the above method. Reference may be made in particular to the description of the embodiments of the method described above.

Alternatively, the memory 32 may be separate or integrated with the processor 31.

When the memory 32 is a device separate from the processor 31, the apparatus may further include:

A bus 33 for connecting the memory 32 and the processor 31.

The present invention also provides a readable storage medium having stored therein a computer program for implementing the methods provided by the various embodiments described above when executed by a processor.

The readable storage medium may be a computer storage medium or a communication medium. Communication media includes any medium that facilitates transfer of a computer program from one place to another. Computer storage media can be any available media that can be accessed by a general purpose or special purpose computer. For example, a readable storage medium is coupled to the processor such that the processor can read information from, and write information to, the readable storage medium. In the alternative, the readable storage medium may be integral to the processor. The processor and the readable storage medium may reside in an Application SPECIFIC INTEGRATED Circuits (ASIC). In addition, the ASIC may reside in a user device. The processor and the readable storage medium may reside as discrete components in a communication device. The readable storage medium may be read-only memory (ROM), random-access memory (RAM), CD-ROMs, magnetic tape, floppy disk, optical data storage device, etc.

The present invention also provides a program product comprising execution instructions stored in a readable storage medium. The at least one processor of the device may read the execution instructions from the readable storage medium, the execution instructions being executed by the at least one processor to cause the device to implement the methods provided by the various embodiments described above.

In the above embodiment of the apparatus, it should be understood that the Processor may be a central processing unit (english: central Processing Unit, abbreviated as CPU), but may also be other general purpose processors, digital signal processors (english: DIGITAL SIGNAL Processor, abbreviated as DSP), application specific integrated circuits (english: application SPECIFIC INTEGRATED Circuit, abbreviated as ASIC), and the like. A general purpose processor may be a microprocessor or the processor may be any conventional processor or the like. The steps of a method disclosed in connection with the present invention may be embodied directly in a hardware processor for execution, or in a combination of hardware and software modules in a processor for execution.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the same; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the invention.

Claims

1. A method of processing a vibrating wire spot welding strain gauge, comprising:

2. The method of claim 1, wherein the step of determining the position of the substrate comprises,

The receiving management end updates the configuration information of the bridge twin space configuration based on the strain gauge module and the configuration information to obtain an indication twin space, and the method comprises the following steps:

3. The method of claim 2, wherein the step of determining the position of the substrate comprises,

And according to the uploading operation of the installation end to the submodel unit, invoking a form switching strategy to update the model of the corresponding decomposition module and strain gauge module to obtain a verification twin space, wherein the method comprises the following steps:

4. The method of claim 3, wherein the step of,

When the installation end uploads the installation data corresponding to the sub-model units according to the uploading operation of the installation end on the sub-model units, updating the sub-model units positioned at the decomposition position in the decomposition module to the combination position of the strain gauge module, repeating the steps until the decomposition module does not have the sub-model units, and obtaining a verification twin space, wherein the method comprises the following steps:

5. The method of claim 4, wherein the step of determining the position of the first electrode is performed,

The verification of the installation data corresponding to the sub-model unit based on the customized verification policy to obtain detection data comprises the following steps:

6. The method of claim 5, wherein the step of determining the position of the probe is performed,

The step of retrieving a preset welding spot pixel value based on the automatic detection attribute, and verifying the installation data of the corresponding linkage unit of the corresponding sub-model unit according to the preset welding spot pixel value to obtain detection data comprises the following steps:

7. The method of claim 5, wherein the step of determining the position of the probe is performed,

Based on the manual detection attribute, the receiving management end performs verification operation on the strain gauge module in the verification twin space, verifies the installation data corresponding to the sub-model unit according to the verification operation to obtain detection data, and comprises the following steps:

Based on the manual detection attribute, receiving verification operation of the management end on the strain gauge module in the verification twin space, and calling installation data corresponding to the corresponding sub-model units to the management end according to trigger information of the management end on the corresponding sub-model units in the decomposition module;

8. The method according to claim 6 or 7, wherein,

The detection data update the strain gauge module in the verification twin space to obtain a display twin space, and the display twin space is sent to a management end, and the method comprises the following steps:

9. The method of claim 1, wherein the step of determining the position of the substrate comprises,

Before the step of updating the bridge twin space based on the strain gauge module and the configuration information to obtain the indicated twin space, the method further comprises the following steps:

obtaining each sub-bridge module in the bridge twinning space, wherein the sub-bridge modules have corresponding preset rotation directions and preset rotation angles;

10. A processing system for a vibrating wire spot welding strain gauge, comprising: