RU2357215C2 - Method of repair and maintenance used in hardware-software complex for diagnostics and system for quality control of repair and maintenance - Google Patents

Abstract

FIELD: information technology.

SUBSTANCE: invention relates to the field of repair and maintenance of complex technical products, for example locomotives, ships and aircrafts. According to the invention step by step information collection about the objects being repaired is carried out via diagnostics of objects of each specific group using measuring equipment, connected to the local server, which controls the process of measuring parametres of a preliminarily identified object. They provide the possibility of electronically processing the diagnostics results in two levels: the local server of a specific group and the mainframe, which collects information from local servers of all specific groups. Possibility of independent evaluation of the results of diagnostics, which also means maintenance standards, are provided due to the equipment and local servers of each of the groups of objects and computer system of an autonomous data base. Hardware-software complex includes a means of identification of the object and user.

EFFECT: system for the control of repair quality and maintenance is made with the capability of connecting to the internet and makes it possible to carry out complex, operative and timely repair quality control and maintenance.

25 cl, 2 dwg

Description

FIELD OF THE INVENTION

The invention relates to the field of repair and maintenance, mainly complex technical products, consisting of a large number of different units and assemblies, for example, large vehicles: locomotives, ships, aircraft, etc. The invention is intended for quality control of repairs and maintenance.

State of the art

A known method of repair and maintenance of cars, tractors and other agricultural machines, consisting of a large number of functional units (see application for invention No. 93015340, IPC: B60S 5/00, publ. 01.27.97), including dismantling, repair and recovery, assembly, running-in, testing, assembly and installation, control and measuring and regulatory processes. The information indicated in the source suggests that the method provides for monitoring the technical condition of repaired and already assembled units, however, this information does not make it possible to judge the quality control of the functional units included in the unit, and the possibility of correlating this quality to a specific repair contractor. In this case, the failures of any functional unit during the operation of a larger vehicle, for example, a locomotive or rolling stock of a railway transport, an airplane, etc., are unpredictable and can have serious consequences. As a result of this, more stringent requirements are imposed on the quality of repair of functional units of the mentioned vehicles, which is caused, first of all, by industrial safety.

There is a known method of repair and maintenance of electric locomotives, which includes disassembling the product into units, and the latter into components and parts that are subjected to technical diagnostics, repair work based on the diagnostic results, certification of repair objects and quality control of the repair performed, including an assessment of the technical condition of the repaired objects by visual inspection and testing, registration of defects discovered as a result of testing, i.e. inconsistencies with regulatory values, establishing the causes of these defects, determining the contractor and taking appropriate measures (see "Rules for the repair and maintenance of electric locomotives ChS2, ChS3, ChS4 and ChS4 ¹ ", Moscow: Transport, MPS, 1982). A characteristic feature of the known method is the aggregate repair principle, which makes it possible to track the quality of each functional unit and, using the property of their interchangeability, to prepare replaceable units for installation on an electric locomotive in advance, while the production flow taking place implies a sequential transition of performers and repair objects from one technological operation to other. Accounting for the implementation of repair work and tracking the movement of the latter is carried out by maintaining various technical documentation: passports of units, repair books, the logbook of the technical condition of the locomotive, etc. The disadvantage of this method is that at almost all stages of diagnostics and quality control of repairs, the accuracy and reliability of information on repaired objects entirely depends on the qualifications and conscientiousness of the performers performing diagnostics and repairs and the masters who control the process. At the same time, it is very time-consuming to analyze records made in journals and books using various algorithms, which does not allow you to quickly make the necessary selection and does not guarantee against errors, while the relevance of operational repair data is lost.

As the closest analogue for the proposed method, the method of repair and maintenance (hereinafter referred to as MOT) is selected, based on the use of the Global EAM information and software management system (MRO) (see www.bitec.ru). The method includes accounting and hierarchical classification of equipment that is the object of repair and maintenance, the use of the barcode mechanism for equipment instances, scheduled inspections and diagnostics by measuring parameters characterizing the facility’s performance, repair work, including the elimination of defects identified as a result of diagnostics, and quality control repair and maintenance, including an assessment of the technical condition of the repaired facility by its diagnosis and its qualitative assessment, accounting for identified defects goods, their classification and quantitative analysis, tracking repair work, registration of the facts of elimination of defects.

The advantage of this method is the possibility of automated (through the use of the capabilities of the computer and its software) accumulation, centralized storage, systematization in the form of various electronic databases (magazines and directory directories) and information processing, which improves the efficiency of repair and maintenance processes, reduces the complexity of work on certification and reporting. However, the registration of the detected defect, its description and purpose is carried out by the operational employee by making the appropriate entries in the electronic accounting journal. Entering information on the results of verification of the repaired object in the computer memory is also carried out by an employee of the metrology unit. With this form of control, it is practically impossible to reliably determine how correctly measurements were taken, while it remains possible to adjust the obtained measurement results. All this reduces the quality of repair work and does not allow to ensure high reliability of the repair objects during operation.

As the closest analogue for the claimed system for monitoring the quality of repairs and maintenance, a well-known system was selected for monitoring the quality of repairs and maintenance, which is part of an integrated repair and maintenance system based on the use of the Global EAM information and software system (MRO) (see . www.bitec.ru). The system contains computers with specialized software, including a set of server and application applications that provide automated collection, storage and analysis of information, and diagnostic tools that are part of the metrological units of the enterprise.

The advantages of the known system is the possibility of centralized storage and electronic processing of information. However, the system, as well as the method, does not guarantee the accuracy and objectivity of the measurement information obtained as a result of diagnostics, because the latter directly depends on the qualifications and conscientiousness of the performer performing the measurements, and the correctness of entering information into the computer's memory. In addition, it is impossible to judge the speed of evaluating the results of diagnostics and its analysis and the timeliness of the system's response to the analysis in order to improve the quality of repairs from the source.

A well-known mobile repair and diagnostic complex is intended for quality control of typical functional units of complex products (see application for invention No. 2005110983, IPC: B60P 1/14, publ. 2006.10.20), containing specialized jobs for specialized repair monitoring and diagnostics of functional units, sets of spare parts and documentation. The complex is mobile and modifiable, however, it does not automatically monitor the quality of repair work.

The closest analogue for the claimed hardware and software complex adopted an automated system for monitoring and diagnosing malfunctions of replaceable functional units REA (see patent for invention No. 2257604, IPC: G05B 23/02, publ. 2005.07.27). The complex includes a computer (assuming the presence of a server device with software and means for inputting and outputting information) connected via a local highway for data exchange with measuring equipment, including a set of electronic measuring and converting modules and means for interfacing with the diagnosed object.

The advantage of the known solution is the automation of measurement processes, because the readings are transmitted directly from the measuring equipment to the memory of the computer that controls the measurement process, thereby eliminating the subjectivity of taking readings, as well as the possibility of electronic processing of the measurement results by comparing the obtained values with the reference ones.

A disadvantage of the known complex is the need for each process to carry out diagnostics of forming tests, programming the appropriate modules and entering limit standard values into the computer’s memory, depending on the type and type of diagnosed object, which reduces the efficiency of diagnostics. In addition, the computer serves only one workstation.

Disclosure of invention

The claimed invention solves the problem of improving the quality of repair work of complex technical products by providing a comprehensive, i.e. covering all stages, timely and effective control of repair and maintenance processes.

The problem is solved due to the fact that in the repair and maintenance method, including the classification and coding of objects to be repaired and maintained, by assigning an identification mark to each object, the object’s diagnostics by measuring the parameters characterizing its operability, repair work based on the diagnostic results, carried out using the capabilities of the computer and its software management of repair and maintenance processes, accumulation, center the storage and visualization of information about the facilities and their certification, as well as the quality control of repairs and maintenance, including an assessment of the technical condition of the repaired facility through its diagnosis and a qualitative assessment of the results of the latter, accounting, classification and quantitative analysis of defects identified by a qualitative assessment and monitoring of repair works, according to the claimed invention, the diagnosis of objects of each species, according to the classification, groups carried out they are installed using specialized measuring equipment connected to the local server, preliminary measurements are performed to identify the artist and the object by reading their identification marks to the local server, which controls the process of measuring the parameters of the identified object, the measurement results are transmitted directly from the measuring equipment to the local server via communication line, where they form a measurement protocol containing information about the object, the performer, the measurement results rhenium and the actual time of their performance, the information grouped in the protocol is stored in the local server and transmitted via the information communication channel to a computer that collects information from the local servers of all species groups, while a qualitative assessment of the diagnostic results is carried out in the local server by comparing the measurement results with standard values parameters stored in its memory and in the computer by comparing the measurement results with the standard values of the parameters stored in the computer memory, identified as a result ltate last-mentioned assessment of defects is used for the quantitative analysis of establishing the existence and causes of repairs marriages, given that corrects the repair process by passing through channels of information communication control actions from a computer on the local server group.

The problem was also solved due to the fact that in the hardware and software complex for diagnostics containing a local server with input and output information, with software that implements the functions of controlling measurement processes, collecting, storing measurement results and comparing them with standard values, and measuring equipment associated with the said server with a local highway for data exchange and containing measuring and converting modules and means for interfacing with the diagnosed object, with According to the claimed invention, the measuring equipment is arranged in at least two work stations, each of which contains an electronics unit, including measuring and converting modules and means for interfacing with the diagnosed object, while each work station is equipped with a terminal module connected to the corresponding electronics unit, containing a keyboard, alphanumeric display and facility identification tools, while the local server is equipped with a local database containing a list of workstations in the list of artists, information about the object being diagnosed and monitored parameters, and local highway for data exchange is made in the form of two-way communication line, sequentially connecting the working positions and the local server.

The problem is also solved due to the fact that in the system for monitoring the quality of repairs and maintenance, containing computers with appropriate software and diagnostic tools, according to the claimed invention, diagnostic tools are made in the form of at least one hardware-software complex according to .11 (above), the local server of which is connected through the channel of two-way communication with the said computer, made in the form of an integrated server device, including a server for storing databases data, system and file server, the software of which provides two-way data exchange with local servers, accumulation, qualitative assessment and quantitative analysis of information received from local servers using information about the limit values of the controlled parameters of objects that supplement the mentioned databases, and a working dispatch a station associated with said integrated server device.

The claimed invention allows to obtain a new positive technical result, namely: the possibility of phased electronic collection of control information about each repaired object, which eliminates the influence of the "human" factor at all stages and ensures the accuracy and reliability of the information received and the possibility of electronic processing at two levels :

local server and computer.

"Qualitative assessment", it is also called "tolerance control" allows you to assess the compliance or non-compliance of the monitored parameters to their normative values. If the measured parameters are within the limits allowed by the standards, then the object “corresponds to the norm”. If the values of the measured parameters go beyond the mentioned limits, then the object "does not correspond to the norm."

Conducting a qualitative assessment of the diagnostic results in the local server ensures the efficiency of defect detection, i.e. inconsistencies of the parameters with standards, which indicates the presence of defective repair work. In this case, the identification of a defect at the species group level allows the contractor to receive timely and highly qualified advice with recommendations on how to eliminate the identified defect from specialist objects that are highly specialized in this type of object. Such a specialist, for example, is an electrical engineer in the control of electrical equipment and a mechanical engineer in the case of control of any mechanisms, etc.

Efficiency of detecting defects and the possibility of obtaining the aforementioned highly qualified consultation allows you to quickly and accurately eliminate the identified defect, eliminating the marriage of repair work. Thus, a quality assessment at the local server level provides quality control over the repair of individual functional units.

At the same time, performing a qualitative assessment at the computer level (i.e., the entire repair enterprise) provides a further quantitative analysis of the defects identified as a result of the qualitative assessment and allows one to get a general picture of the repair status, i.e. the entire complex technical product, as well as for each object, performer, species group of objects.

The ability to transfer control actions, formed on the basis of the results of quantitative analysis, through information communication channels from the computer to the local servers of the groups, allows you to quickly and timely adjust repair schedules, redistribute labor and material resources, as a result of which prevent delay of repair processes and disruption of repair and maintenance schedules , which means to prevent the operation of facilities whose overhaul mileage exceeded permissible standards, which is unsafe.

The classification and, in accordance with it, the division of repair and maintenance objects into specific groups and within the latter into smaller and standard ones, allows not only to use specialized, and therefore more high-precision equipment to diagnose each group, which allows to increase the accuracy and quality of diagnostics, but also provides the possibility of electronic data collection using the capabilities of microprocessor devices and their software. In this case, the necessary condition is the identification of the object by reading its identification tag by the local server, which controls the process of measuring parameters in the order corresponding to the type of object, information about which contains its identification tag.

Thus, the claimed method of repair and maintenance provides a comprehensive, timely and effective control and high responsiveness to the results of control, which ensures high quality repair and maintenance work.

By conducting preliminary diagnostics of the identification of the object and the contractor, they also provide the possibility of forming a single electronic document containing all the information necessary for monitoring, which facilitates the processes of further analysis, preparation of object passports and reporting, and provides the possibility of correlating the results of work to a specific contractor, which determines a more conscientious the attitude of the latter to work.

The hardware-software complex is designed to implement part of the operations of the method, namely: all stages of the diagnosis, from input to output control. The hardware-software complex (hereinafter referred to as the AIC) provides automatic (electronic) collection of measurement information and its qualitative assessment, which eliminates the “human factor” and ensures the objectivity and reliability of measurement information and control results. At the same time, unlike the prototype, the agro-industrial complex provides specialization of control processes by types of objects due to the layout of measuring equipment in specialized posts. This specialization makes it possible to increase the efficiency of diagnostics and its assessment due to the possibility (since repair objects are known in advance) of equipping the local server with a local database containing the necessary information about the objects.

The inventive system for monitoring the quality of repairs and maintenance is also intended to implement part of the operations of the proposed method, aimed at implementing quality control, and includes at least one of the aforementioned hardware-software complex. The composition and interconnections of the components of the claimed system also allow electronic collection of measurement results when diagnosing an object and electronic information processing first in the local server of the species group, and then in a computer that collects information from all local servers.

Thus, the claimed objects of the invention are intended to solve the same problem and allow you to get the same technical result, and therefore form a group of inventions connected by a single inventive concept.

Another advantage of the proposed solution is the availability of independent databases: a local database - in each local server, and a generalized one, i.e. containing information about all serviced objects, regardless of type, in a computer, which provides the possibility of an independent qualitative assessment at each level. Thus, the computer plays the role of a “supervisory authority” performing independent verification (control) of the results of the qualitative assessment carried out at the local server level. The computer provides confirmation of the results of control carried out at the level of the agro-industrial complex, which serves as a guarantee of the quality of control of repair work, which means that it excludes the possibility of exit from repair of components that do not correspond to the proper level of quality and reliability.

The presence of an independent local database provides the possibility of autonomous use of any agribusiness for quality control of repair of species group objects.

The preferred application of the claimed invention is the repair and maintenance of complex technical products (hereinafter - STI), such as locomotives, ships, aircraft, etc. In this case, the components of the STI, i.e. its functional units. The possibility of high-quality and operational control of each functional unit, and at the same time, the possibility of carrying out generalized control for all groups of objects included in the STI, ensures high quality and reliability of the entire product in the assembly.

Another advantage of the claimed invention is the ability to repair any objects, i.e. functional nodes, without linking the latter to any particular enterprise, because each object is encoded (marked) independently and identified as an independent unit, which allows you to trace its history, condition and movements, for example, when installed in another complex technical product.

In the specific case of the invention, a unique barcode containing information about the object can be used as an identification mark of the object. However, the latter does not limit the possibility of using any other known encoding method, for example, using radio or other tags that allow their automatic reading.

The barcode is formed in the corresponding local server using the local database of the latter, printed out and pasted onto the object. Marking is carried out at the initial receipt of the latter for repair, in the future the barcode remains at the facility.

In case of repair of a complex technical product (STI), i.e. When the functional units and components of the STI are used as repair objects, it is preferable to put the following information in the barcode: the unique serial number of the object, its type and type, taking into account the specific location in the STI scheme, information about the latter and the operational unit to which the object is assigned.

As an identification mark of the contractor, you can use his personnel number.

It is important not only to control the quality of each individual object, but also to assess the quality of the whole STI as a whole, for which an additional assessment of the technical condition of the repaired object is carried out by testing it in real load conditions, i.e. in assembly with adjacent nodes. Such tests are also called run-in. The results of measurements made during these tests are also transferred to the corresponding local server, where they establish their compliance (or non-compliance) with the standard values, and then to the computer for further analysis, which provides the possibility of a comprehensive analysis of the quality of the repair, improves the accuracy and objectivity of establishing the causes marriage repair.

Quantitative analysis is carried out using specialized computer programs and the classifier of defects contained in its information base, data on the actual time spent in repair, information on the object’s behavior during the overhaul period. At the same time, the sequence of actions of the method and the grouping of all the information necessary for analysis in a single electronic document allows you to quickly correlate the identified defects to each specific artist, workplace, etc. By the number of defects and the actual time the object was in the repair, a quantitative analysis allows us to establish the presence of defects in the repair work, identify the causes and trace the dynamics of the said defects.

The claimed solution provides for the possibility of exchanging information with other enterprises where similar systems are used. Providing access to the computer database of third-party users can be carried out through the Internet. The possibility of multi-user and remote access allows you to create a single information base, for example, of an industry, and the speed of exchanging data on repaired objects will reduce the time and laboriousness of repairs and maintenance and reduce the number of defects in repair work at all its enterprises.

In the case of repair and maintenance of a complex product, both each unit individually and a complex technical product (STI) as a whole are certified. Functional nodes are certified in the local server of the species group by forming an electronic measurement protocol and printing the latter. The certification of a complex technical product is carried out in a computer by forming a generalized electronic passport containing information about all the functional components making up the product.

Tracking of repair work can be carried out by visual representation of the repair process in real time, for example, using tables and / or graphs and / or mimics.

The preferred embodiment of the agro-industrial complex is its specialization for one type of objects. The work posts that make up the agro-industrial complex specialize in typical groups within this type. Means of interfacing with the diagnosed object in this case is preferably performed in the form of a set of devices appropriate for the type of object: cables, measuring probes, sensors, terminal strips, etc. By equipping the workstation with specialized means of interfacing with the object, debugging and high speed of measurement processes are achieved, therefore, the efficiency of diagnostics is increased, and its complexity is reduced.

In the specific case of the agro-industrial complex, the means of identifying the object can be made in the form of an optical scanner, which allows you to automatically read the identification marks of objects - barcodes to the local server.

The local server information output means must contain at least one printer for printing measurement protocols and barcodes.

It is preferable to perform measuring and converting modules of the electronic unit based on microprocessors interconnected to form a distributed data acquisition system.

It is advisable to place the electronics unit and the terminal module on one vertical rack, while in order to increase ergonomics and ease of use, the terminal module can be mounted on the rack by means of a pantograph.

In a specific case of implementing a system for quality control, a work dispatching station can be implemented on the basis of a personal computer, the application software of which has a graphical intuitive user interface and provides the following functions: input of information, receipt of information in electronic form from local servers, presentation and viewing information in tabular and graphical forms, reflection of information in real time, display of information on a monitor screen in graphic com and in the form mimics, tracking moving objects, forming and printing reports.

It is preferable to equip the dispatch station with an additional overview screen with a large diagonal to display the mimic diagram of the repair process, which includes graphic labels that show the location of the object at the repair positions and its condition.

Graphic labels can be made in the form of color indicators that reflect information in real time and change their color when passing control deadlines.

The mimic diagram may be configured to display information in accordance with the actual spatial layout of each hardware-software complex and / or system as a whole.

Brief Description of the Drawings

Figure 1 shows the structural diagram of a system for monitoring the quality of repairs and maintenance.

Figure 2 is a structural diagram of a hardware-software complex for diagnostics.

The implementation of the invention

The inventive method of repair and maintenance was carried out through the inventive system for quality control and a hardware-software complex based on a repair locomotive depot, already containing technical means for repairing locomotives.

To implement the method in the depot was installed a system for quality control of repairs and maintenance, presented in figure 1. The system consists of a repair control center (SDG for short), which includes an integrated server device 1, a dispatching workstation 2 and network communication devices that organize channels 3 of two-way information communication, and hardware and software complexes 4, each of which is designed to diagnose objects of a certain type and includes a local server 5, measuring equipment, staffed in work stations 6, associated with the mentioned server 5 local highway 7 for data exchange.

The SDGs are implemented on the basis of standard equipment and computer equipment equipped with specialized software. The server part of the SDGs (device 1) includes a database server (DBMS InterBase), an OPC system SCADA-system server, and a file server for file exchange operations between various SDG software components and complexes 4. Dispatch station 2 is based on a personal computer with an application software necessary for the work of the repair manager (including a set of standard applications “ASUT-T”, “Log of the driver’s comments”, “GUID”, the application “Dispatcher”, the client component of the SCADA system and applications for visualization of various x mimics). Station 2 is equipped with an overview screen 8 with a large diagonal to display the depot mimic.

Network communication devices, including modems, network connection switches, etc., provide communication over network protocols between a complex server device 1, a work dispatch station 2, local servers 5 and workstations of third-party users 9, which may include a central dispatch center ( a single database server) industry.

The system may contain any number of hardware-software complexes 4, determined by production necessity. In a specific case for a locomotive repair depot, it can be: a complex for the diagnosis of electric vehicles of traction rolling stock, a complex for diagnostics of brake systems, a complex for diagnostics of traction motors, etc. The agro-industrial complex can be mounted in the repair units corresponding to the type of objects or independently of them.

The structure of AIC 4 is also universal, i.e. allows you to work with any required set of working measuring posts 6, the design and spatial location of which is determined by the needs of a particular repair production. For example, the agro-industrial complex for the diagnosis of electrical devices includes the following work stations 6:

RP1 - control post of high-speed switches,

RP2 - control post of electromagnetic contactors,

RP3 - control post for relays and panels,

RP4 - control post of protection devices,

RP5 - post control of starting resistance, etc.

All work stations 6 are connected in series with the local server 5, and the local server 5, on the basis of which the wizard's workplace (hereinafter referred to as RMM), is always the last one in this chain. The memory of server 5 contains: a list of workstations, a list of performers, information about the diagnosed objects and their monitored parameters, which form its local database.

The RMM also includes a monitor 10, a keyboard 11, and a printer 12 connected to the local server 5 (see FIG. 2). A specific implementation of the wizard's workplace can be carried out on a PC, the system configuration of which meets the following requirements: processor type - Pentium 4, Celeron, with a clock frequency of at least 1 GHz, RAM capacity of at least 128 MB, and Windows XP Professional operating system SP1, and the size of the disk space is at least 100 MB.

As a local highway 7 for data exchange, the RS-485 communication line can be used.

The workstation 6 includes an electronics unit 13 and a terminal module (or, briefly, a terminal) 14 mounted on a support column 15. Unit 13 contains a set of unified microprocessor modules 16 located in the housing for receiving information from primary converters and converting it to digital form, terminal strip 17 for connecting network cables and connectors 18 for connecting means of interfacing with the diagnosed object, made in the form of a specialized set of 19 different devices: measuring probes, with connecting cables, sensors, etc.

The terminal module 14 contains a keyboard 20, an alphanumeric display 21 and connectors 22 for connecting a barcode scanner and 23 for connecting an electronic caliper. The suspension of the terminal 14 is mounted on the rack 15 by means of a pantograph 24, which regulates the height of the terminal. Terminal 14 is intended for organizing a human-machine interface for controlling the operation of station 6. The dialogue between the operator (executor) and station 6 is carried out by selecting the appropriate menu items displayed on the display 21 of terminal 14.

The method of repair and maintenance is as follows.

A locomotive arriving at the depot for repair or maintenance is registered by the dispatcher of the workstation 2 and installed at one of the repair positions, which is displayed on the depot mimic diagram on screen 8. Electrical devices and other functional units are dismantled from the locomotive, classified by type and type and distributed according to type AIC 4, where they are sorted by type and are installed at the positions of the parameter check, i.e. at the appropriate job sites 6.

The master at his workplace, using the local database of the local server 5, generates unique barcodes for each object to be monitored, and the following information is put into the barcode: locomotive series, locomotive number, registration depot, type of apparatus, type of apparatus, unique serial number of the apparatus . Barcodes are printed on printer 12 and distributed to work stations 6, where it is glued to a non-current-carrying element. If an object (device) is repaired and already contains such a barcode, then re-encoding is not required. The mentioned barcode is stored throughout the "life" of the object.

Using the appropriate interface device 19, designed to measure a specific parameter, connect the diagnosed object to the connector 18 of unit 13. Carry out the identification of the object, for which an optical scanner is connected to the terminal 22 of the terminal 14, in the main menu of the terminal 14 select the corresponding item and read it from the object barcode, the latter arriving at the local server 5 and reflected on the monitor screen 10 of the RMM and on the display 21 of the terminal 14.

The artist performing the measurements is identified, for which, using the keyboard 20, the corresponding menu item of the terminal 14 is selected and its personnel number is entered.

Server 5, after deciphering the barcode, extracts the parameter measurement program and data on the normative (limit) values of these parameters from its memory and controls the measurement process by interrogating the parameters using the corresponding algorithm. The measurement results are displayed on the display 21 of the terminal module 14 and transferred to the database of the local server 5 automatically as they are monitored, provided that the device has been identified (in the absence of barcode scanning, post 6 works in tester mode).

The local server 5 provides a qualitative assessment of the monitored parameter (performs tolerance control) by comparing the measurement result with standard limit values from the local database.

Thus, the operator-operator performs only the installation of the object on the stand and its connection. The measurement results are taken and processed automatically, which makes it possible to obtain a valid, i.e. objective accurate information about the parameters of a particular node and objectively evaluate the quality of repair.

Upon completion of the diagnosis, the following information is displayed on screen 10 of the RMM: abbreviation of the workstation, last name and initials of the performer, type of object, measurement results, real time of the measurements. This information (or electronic measurement protocol) is printed on the printer 12 and pasted into the passport of the object.

A specialist in the relevant field, for example, a foreman or engineer, based on the results of diagnostics, consults the contractor, issues recommendations for eliminating the detected defects.

The agro-industrial complex allows for input diagnostics, the results of which carry out repair work, if necessary, intermediate diagnostics and output control of the repaired object.

Information about the current repair, grouped automatically in the measurement protocol with an interval of one minute, is transmitted via information channel 3 from the local database of server 5 to the general one, i.e. in the SDGs, where it is stored and analyzed in the integrated server device 1, and can also be displayed on the screen of the control station 2 at the request of the repair manager.

An additional assessment of the technical condition of the repaired object by testing it under real load conditions can be carried out in the same agricultural sector where the object was diagnosed. For carrying out tests under load in this agro-industrial complex, a specialized workstation 6 is used. The test results are automatically recorded similarly to the above diagnostic process. In another specific case of implementing the method, an additional assessment can be carried out in a specialized agro-industrial complex, while the test server 5 receives and processes the test results, the information is also transmitted to the SDGs.

Based on the data received from the local servers 5, the integrated server device 1 first carries out a qualitative assessment of the measurement results using its database of limit values, and then a quantitative analysis of the defects detected as a result of the qualitative assessment. According to the number of defects detected for each object, the actual time the object was under repair, using the information about the object’s behavior during the overhaul period from the site of the facility’s operation in the SDGs, they establish the causes of defects in repair work, classify them, track the dynamics and analyze the reasons for their increase quantity. The reasons for this increase, in accordance with the classifier of defects contained in the memory of server 1, may be: defective components, poor-quality materials, human factor, violation of repair technology. The information grouped in a single electronic document (measurement protocol) allows you to easily and quickly establish the contractor and the workstation where the diagnosis was made. In server 1, the corresponding control actions are formed, aimed at eliminating the causes of defects, which are transmitted via information communication channels back to the local servers of 5 groups.

The repair manager, using PC software applications 2, monitors the time spent on locomotive repair and records the movement of locomotives by repair positions, which is displayed on the PC screen 2 in the form of various tables. The presence of the overview screen 8 allows the repair manager to simultaneously work with the dialog application for registering locomotives and have a mimic diagram of the depot with the location of locomotives at repair positions or a mnemonic of the repair process with the deployment of units of repair objects that reflect data received from local servers 5. Territorial location of graphic labels on mnemonic diagrams in accordance with the actual location of repair positions and workshops and the possibility of color display of information means It simplifies and facilitates the work of the dispatcher.

The resulting comprehensive assessment of the technical condition of the locomotive after repair allows us to guarantee its reliability for the entire overhaul period, while significantly reducing the cost of repairs and maintenance, increasing the operational reliability coefficient of nodes (repair objects), and optimizing the volume of maintenance and repairs.

Claims (25)

1. A method of repair and maintenance, including the classification and coding of objects to be repaired and maintained, by assigning an identification mark to each object, diagnostics of the object by measuring the parameters characterizing its operability, repair work based on the results of diagnostics carried out using the capabilities of a computer and its software, management of repair and maintenance processes, accumulation, centralized storage and visual representation other information about the facilities and their certification, as well as quality control of repairs and maintenance, including an assessment of the technical condition of the repaired facility by its diagnosis and a qualitative assessment of the results of the latter, accounting, classification and quantitative analysis of defects identified by a qualitative assessment and monitoring of repair work, characterized in that the diagnosis of objects of each species, according to the classification, groups are carried out using a specialized meter of the equipment connected to the local server, preliminary measurements carry out the identification of the executor and the object by reading their identification marks to the local server, which controls the process of measuring the parameters of the identified object, the measurement results are transmitted directly from the measuring equipment to the local server, where the measurement protocol is generated containing information about the object and the performer, the measurement results and the actual time of their implementation, grouped in the protocol, information is stored in a local server and transmitted via an information communication channel to a computer that collects information from local servers of all species groups, while a qualitative assessment of the diagnostic results is carried out in the local server by comparing the measurement results with the standard values of the parameters stored in its memory, and in a computer by comparing the measurement results with the standard values of the parameters stored in the computer memory, the defects identified as a result of the last mentioned assessment use d For a quantitative analysis that establishes the presence and causes of defects in repair work, taking into account which they correct the repair process by transferring control actions from computers to local group servers via information communication channels. 2. The method according to claim 1, characterized in that as objects use components - functional units of a complex technical product. 3. The method according to claim 1, characterized in that as the identification tag of the object using a unique barcode, which is formed in the corresponding local server. 4. The method according to claim 1, characterized in that the personnel number is used as an identification mark of the performer. 5. The method according to claim 1, characterized in that they carry out an additional assessment of the technical condition of the repaired object by testing it under real loads, the test results are transmitted to the corresponding local server, where they are qualitatively evaluated, and then to a computer. 6. The method according to claim 1, characterized in that the quantitative analysis is performed using specialized computer programs and the classifier of marriages contained in its information database, the data of measurement protocols and information about the behavior of the object during the overhaul period. 7. The method according to claim 1, characterized in that they provide access to third-party computer information base via the Internet. 8. The method according to claim 2, characterized in that the certification is carried out by each node individually and a complex technical product as a whole. 9. The method according to claim 1, characterized in that the tracking of the repair work is carried out by means of a visual representation of the repair process in real time on a computer screen. 10. The method according to claim 9, characterized in that the visual representation is carried out through tables, and / or graphs, and / or mnemonic diagrams. 11. Hardware-software complex for diagnostics of repair and maintenance objects, containing a local server with input and output information, with software that implements functions for controlling measurement processes, collecting, storing measurement results and comparing them with standard values, and measuring equipment, connected to the said server with a local highway for data exchange and containing measuring and converting modules and means for interfacing with the diagnosed object, characterized in that the measuring equipment is arranged in at least two work stations, each of which contains an electronics unit including measuring and converting modules and means for interfacing with the diagnosed object, each work station having a terminal module connected to the corresponding electronics unit, containing a keyboard, alphanumeric display and means of identification of the object, while the local server is equipped with a local database containing a list of work posts, a list of Itel, information about the object being diagnosed and monitored parameters, and local highway for data exchange is made in the form of two-way communication line, sequentially connecting the working positions and the local server. 12. The complex according to claim 11, characterized in that it is made specialized for objects of the same type, and its work posts are performed specialized in typical groups within this type. 13. The complex according to claim 12, characterized in that the means of interfacing with the diagnosed object is made in the form of a set of cables, measuring probes, sensors, terminal strips corresponding to the type of object. 14. The complex according to claim 11, characterized in that the facility identification means is made in the form of an optical scanner connected to a terminal module. 15. The complex according to claim 11, characterized in that the local server information output means include at least one printer for printing measurement protocols and barcodes. 16. The complex according to claim 11, characterized in that the measuring and converting modules are microprocessor-based and interconnected to form a distributed data collection system. 17. The complex according to claim 11, characterized in that the electronics unit and the terminal module are mounted on a vertical rack. 18. The complex according to 17, characterized in that the terminal module is mounted on a vertical rack by means of a pantograph. 19. The complex according to claim 11, characterized in that the local server is located in a separate room. 20. The system for monitoring the quality of repairs and maintenance by the method according to claim 1, containing a computer with appropriate software and diagnostic tools, characterized in that the diagnostic tools are made in the form of at least one hardware-software complex according to claim 11 the local server of which is connected through the channel of two-way communication with the said computer, made in the form of an integrated server device, including a server for storing databases, system and file server, software of which provides two-way communication with the local servers, storage, qualitative assessment and quantitative analysis received from the local information server using the information on the limit values of controlled parameters of the objects, which are supplemented mentioned database, and the operating control station associated with said integrated server device. 21. The system according to claim 20, characterized in that the work control station is implemented on the basis of a personal computer, the application software of which has a graphical intuitive user interface and provides the following functions: input of information, receipt of information in electronic form from local servers, presentation and viewing information in tabular and graphical forms, displaying information in real time, displaying information on a monitor screen in graphical form and in the form of a mnemonic diagram, zhivanie moving objects, forming and printing reports. 22. The system according to item 21, characterized in that it is configured to connect third-party users via the Internet. 23. The system according to item 21, wherein the dispatching station further comprises an overview screen for displaying a mimic diagram of the repair process with graphic labels showing the location of the object at the repair positions and its condition. 24. The system according to item 23, wherein the graphic labels are made in the form of color indicators that reflect information in real time and change their color when passing through the control deadlines. 25. The system according to item 23, wherein the mimic diagram is configured to display information in accordance with the actual spatial layout of each hardware-software complex and / or system as a whole.

Images