RU2548693C1 - Multifunctional maintenance and repair centre (mmrc) - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: multifunctional maintenance and repair centre (MMRC) includes a stationary repair centre (SRC), and a surface-to-air missile repair station (SAM RS) and a training centre (TC) which are additionally introduced to the MMRC. The SAM RS is located in a separate facility and is fitted with process work places (PWP). The PWP comprise automated work places (AWP) and automated process and resource control system (APRCS). All AWP are connected to the ACS of the SAM RS. The ACS of the SAM RS by its external main line is connected to an automated technical availability control system (ATACS) included in the SRC. A training centre (TC) is additionally introduced in the MMRC. The TC is operated under the control of TC ACS connected to the ATACS. A complex proof ground (CPG ACS) is included in the MMRC and comprises a set of automated test units which is operated under the control of the respective CPG ACS. The CPG ACS is connected to the ATACS by the external interface main line.

EFFECT: improved efficiency and immediacy of works, provision for higher stability and persistence of a multifunctional maintenance and repair centre.

4 cl, 11 dwg

Description

The invention relates to the field of maintenance and repair of weapons systems and military equipment.

Stationary repair centers and mobile repair centers (sets of mobile repair and diagnostic complexes) are known that contain a combination of technological equipment that implements technological cycles of repair of weapons and military equipment (IWT) and their components (MF).

Examples of such technical solutions are solutions for patents RU No. 2427020 and RU No. 2491186.

Closest to the claimed invention is a stationary repair center (SRC) according to patent RU No. 2491186, adopted as a prototype in relation to the claimed multifunctional center for maintenance and repair (MTTR).

The device, the principle of operation and application features for the intended purpose of the SSC according to the patent RU No. 249118 (prototype) are explained in figure 1, figure 2 and figure 3.

The stationary repair center according to the patent RU No. 2491186 is created in a stationary production building, which can be used as existing repair enterprises (with appropriate reconstruction and re-equipment), as well as newly constructed industrial buildings specially designed for SSC. In the building of the SEC, the production and technological components of the SEC are functionally interconnected during the implementation of the through technological cycle of product repair in the form of workshops and sections, the composition of which is determined by the composition of the functional groups of the components of the repaired products and the types of work on them (see Fig. 1) , including the workshop for fault detection, disassembly, assembly and adjustment of products, the workshop for repair of electromechanical components of products, the workshop for repair of mechanical components of products, the workshop for repair of hydraulic systems parts, repair shop for internal combustion engines, repair shop for power supplies, repair shop for electronic equipment, repair shop for ventilation and air conditioning, workshop for calibration and repair of instrumentation, repair shop for communications and topographic referencing, workshop for repair of basic chassis and mobility products , a workshop for repairing bodies and containers, connected via power supply and utilities to the life support subsystems of the SRC, as well as a testing ground for complex tests Cereal renovated SRP and control center with a central part located technical readily automated control system IWT groups (ACS TT), as shown in Figure 2. All components of the SSC are interconnected by passages and passages. Production and technological workshops of the SRC are equipped with technological workplaces (TRM) according to the profile of the technological operations carried out for repairing the midrange products and include basic stationary technological equipment - specializing in TRM and an automated workstation for information support of the TPM operator actions (hereinafter referred to as ARM-I) ), consisting of a computer, monitor, feedback manipulator and an identity reader. In addition to the AWS-I, which are part of the TRM, in each workshop and section of the SEC place automated workstations for remote control of work (AWP-UR). The premises of workshops and sections are equipped with access restrictions (for example, in the form of sliding doors) equipped with combination locks and identification data readers. Identification data readers are installed in the control places of passages and passages connecting the main and auxiliary components of the SEC (workshops, sections, automated storage, life support systems, control center) among themselves. Remote controlled digital video cameras are installed in the premises, walkways and passages of the SRC. All peripheral AWS (AWS-I, AWS-UR), identification data readers and digital video cameras are connected to the central control system computer located in the control center of the control center through the information center of the SSC and communication equipment.

The display screen of the current situation and the control monitors of the video surveillance system of the SSC are connected to the central control system computer in the control center of the SEC. Replaceable sets of technological equipment of TPM are located in the automated storage center of the SRC, designed to adapt the TPM to the specifics of repairing the midrange from various types of military hardware, as well as sets of materials, tools, spare parts and other property used in the repair of products in accordance with the repair documentation. For all types of property moved within the SSC during the repair process, identifiers are installed that interact with the identification data readers installed in the control centers of the SEC, as well as as part of the ARM-I and ARM-UR. Identifiers are also placed on the midrange from the composition of the products being repaired and from the composition of spare sets, on technological vehicles used in the SEC, and on the staff of the SEC.

Before starting work on the repair of each next type of product, the interactive control documentation (IED) is placed in the database of the central computer of the automated control system of the automatic control system, with the help of which automated situational control is carried out for the implementation of all the work through the technological cycle of product repair as part of the SSC (an example of a structural diagram of such a technological cycle shown in figure 3).

Through remote access channels, remote access terminals can be connected to the central computer of the automated control system of the TG, located at the locations of the regular deployment of controlled arms and military equipment from the serviced territorial arms and military equipment group and used to monitor the technical condition of the military-hardware group.

The creation of the SSC according to patent RU No. 2491186 is carried out in two stages:

1) the creation and equipment of a fully functional SSC in accordance with the declared composition and the declared functional, technological, constructive and informational links between the components of the SSC;

2) implementation of the full technological cycle (method) of repair of military hardware and equipment as part of the SEC.

The creation and equipping of a full-featured SSC begins with an analysis of the features of the full range of types of weapons and military equipment that are planned to be repaired as part of the created SSC. From the nomenclature of the types of products being repaired, a product with the most complex functional, structural and technological structure (for example, an anti-aircraft missile system from the S-300P series, including autonomous components such complex in their structure as a radar, command post, launcher, is selected and etc.).

As a result of the analysis of the structure of this product, which is taken as the base, the characteristic groups of functional components are determined that have similar principles of structural and technological design, as well as repair processes that are similar in their implementation and in the equipment used.

The principle of highlighting the characteristic functional components to optimize the repair process in the composition of the SSC is illustrated in figure 1 on the example of one of the types of air defense systems. As shown in figure 1, the composition of the repaired product 1 includes the following characteristic functional groups of components:

- electronic equipment 1.1;

- Electromechanical units and assemblies (systems) 1.2;

- mechanical components and assemblies 1.3;

- hydraulic units and assemblies 1.4;

- chassis (mobility aids) 1.5;

- ventilation and conditioning systems 1.6;

- communications and topographic location 1.7;

- gas turbine engines (internal combustion engines) 1.8;

- instrumentation 1.9.

Moreover, the repair of anti-aircraft guided missiles 1.10 in the SSC according to patent RU No. 2491186 (prototype) is not provided.

After analyzing the structure of the base (most complex) repaired product, the same analysis of the remaining (less complex) types of repaired products is carried out. As a rule, new additional functional parts affecting the organizational structure of the created SSC are not detected. However, the structural and technological features of the implementation of the functional groups of the midrange from various types of products are revealed, which entail the need for additional technological equipment. Most often, this additional equipment can be implemented in the form of interchangeable kits for basic equipment. For example, plug-in adapters and plug-in software tests for basic diagnostic equipment.

Based on the identification of these features, requirements are formed for equipping the SSC (see Fig. 1) with technological equipment, technical (operational and technological repair) documentation, general industrial equipment, tools, consumables, and spare parts.

Technological equipment for each functional group of components of the repaired products (see Fig. 1) is divided into the basic (used in the repair of all types of products) and replaceable (used in the repair of the midrange from the composition of specific types of products, taking into account the peculiarities of the functional, structural and technological implementation) . Similarly, they divide into the base part and replaceable kits for all other types of property used to provide repair work (components, consumables, spare parts, tools, accessories).

As a result of the analysis of the structure of the types of products to be repaired as part of the SSC, the nomenclature of the component parts (shops, sections) of the SEC is determined, in which the repair work of the component parts of the products must be performed in accordance with the implemented repair technology. An example of the structure of the main production and technological components (units) of the SSC, designed to implement the repair process, is shown in figure 2. As can be seen from figure 2, the main composition of the production components of the SSC 2 is focused on the repair of functional groups of midrange products, selected according to the analysis of structural features of the products according to figure 1. Additions are the workshop (site) of fault detection, disassembly, post-repair assembly and adjustment of the product being repaired as a whole (position 2.1 in figure 2).

For products of the type of air defense systems and radar, tests which after repair cannot be carried out in full in the workshop room (in the building of the SEC), an additional special training ground is provided (position 2.13 in figure 2).

In addition to the main production and technological components of the SSC, presented on the example of figure 2, when creating the SSC provide for the organization of the necessary supporting and auxiliary subsystems, including:

- the life support system of the SRC (including electricity, water, air exchange, sewage, etc.);

- administrative and auxiliary subsystems (to accommodate managerial and support staff);

- automated storage of replaceable technological equipment, consumables, tools, spare parts;

- an automated control system for the SSC (position 3.0 in figure 2), including the control center of the SSC with a central computer located in it with a screen for displaying the current situation and communication equipment of the information network, through which the central computer is connected to a set of terminals (AWP and identification readers data) posted within the SSC.

The premises as part of the SEC are organized taking into account the requirements for the placement and installation of technological equipment of workshops and sections (see examples of FIG. 1 and FIG. 2) based on the developed layouts and construction documentation. Entrances to the premises of workshops and sections are subject to restrictions on access (for example, in the form of sliding doors equipped with combination locks and identity readers).

All production, technological and auxiliary premises of the SEC are interconnected by passages providing controlled movement of the repaired midrange, equipment, sets of property and personnel of the SEC. To this end, the sections of the aisles are equipped with identification data readers connected to the ACS information network.

To monitor the progress of repair of the midrange products, operational management of the work and ensuring the safety of the SSC, in the control places of the SEC premises and at the transition control points, remote-controlled digital video cameras are installed that are connected to the information system of the ACS and ensure that the current situation is displayed on the screen of the SSC control center.

Depending on the specifics of the controlled objects, two types of identifiers are provided for in the SEC:

1) barcode identifiers;

2) radio frequency identifiers.

Bar-code identifiers are used in those cases when, according to the structural and technological features of objects (small dimensions, undesirable electromagnetic interactions), the use of radio-frequency identifiers is impractical or impossible. Examples of such objects are, in particular: tools, CEA replacement parts, components, small-sized spare parts.

In all other cases (including mid-range products, technological equipment of workshops and sections, technological vehicles, stacking property, personnel of the SEC), radio frequency identifiers known from the prior art are used.

As part of the workshops and sections, technological workplaces (TRM) are organized for the specialization of work (for example, TPM monitoring and diagnostics, TPM of electrical and radio installation, etc.) based on the corresponding standard technological equipment and equipment known from the prior art. Each TRM includes an automated workstation ARM-I (based on a computer, monitor, manipulator and reader of identification data) connected to the information network of the automated control system. With the help of these workstations, I provide information support for the actions of TPM operators and feedback from the central computer of the automated control system (to transmit information about the progress of the repair operations of the corresponding midrange).

In the premises of each workshop and section, an automated workstation for remote control of work (AWP-UR) is installed, connected via an information network to the central computer of the automated control system. With the help of this connection, current monitoring of the progress of work in the workshop (section) and operational remote control of the progress of repair of the midrange are carried out. AWP-I and AWP-UR, which are part of the workshop (site), can be combined into a local network of the workshop (site).

As noted earlier, all the premises of workshops, sections, auxiliary rooms and passages are equipped with remotely controlled digital video cameras connected via an information network to the central computer of the ACS. Using the similarly created video surveillance subsystem СРЦ on the screen of the central control center СРЦ (under the control of the central computer АСУ) and on the screens of the control monitors display the current situation on the repair of the midrange products and carry out operational video monitoring of all work in all the premises of the СРЦ, in transitions and on external sites (including the landfill of the SRC).

Interactive electronic repair documentation (IED) is developed for each type of products being repaired in the SEC (for managing repair processes). The IED is based on the operational survey of the product as a whole and its components - in the sequence of assembly / disassembly processes of each product and its components. Video frames contain an image of each component part of the product in interaction with the tools (tools, fixtures, measuring equipment, materials) used in performing this operation (inspection and fault detection, disassembly, assembly, configuration, etc.). Video frames are accompanied by textual and speech (audio) instructions to the operator on how to complete each operation. The structure of the IED reflects the structure of the product to be repaired. For each component of the product as part of the IED, the corresponding sections and subsections of the IED are included in them (in accordance with the constructive occurrence of the midrange of the lower levels of decomposition of the product structure in the midrange of the higher levels of decomposition of the product structure according to the division scheme).

The developed IED is entered into the knowledge base of the ACS central computer and is subsequently used to control the technological process of repairing complex technical products as part of the SSC and in the places of the standard deployment of product samples (including using mobile SSCs attached to the SEC).

The implementation of the technical solution according to patent RU No. 2491186 (prototype) is based on the use of technological equipment and equipment known from the prior art for the period of creation of the SEC in the workshops and sections of the SSC (see FIG. 2). For example, to carry out the repair of functional groups of midrange products assigned to the created SSC (see Fig. 1), technological equipment and accessories similar to those used at factories for the manufacturing of midrange products (or analogues of this equipment from the prior art for the period of creation) can be used СРЦ, with improved operational and technical characteristics). As materials, components and spare parts in the process of repairing products as part of the SEC, materials, components and components laid down in the design of each type of product during its development (or their modern analogs providing an acceptable replacement) are used.

The creation of the ACS is based on the use of computer technology known from the prior art for the period of creation of the SSC (for example, similar to those used in the creation of the ACS KUSVR according to patent RU No. 2427020).

The implementation of the repair cycle for the components of products being repaired in the SSC is controlled from the premises of the SEC control center, which houses the central control system processor with a screen connected to it, communication equipment that provides communication between the central control computer and peripheral workstations as part of workshops and sections, with identification readers information and with digital video cameras of the video monitoring system of the SRC through the information network of the ACS. On the screen of the control center (under the control of the central computer of the ACS), a plan of the location of the shops and sections and the TPMs that are part of them is displayed, as well as the current performance indicators of the repair operations of the midrange at each TPM, in each section and the workshop, for each item being repaired. The display of the current repair situation is based on the reproduction of informationally related tables of indicators - with their hierarchical relationship and search capabilities for various details (similar to the construction of search structures on the Internet).

On the screen, in the initial state, the main table is displayed, containing a list of products received for repair in the SEC. When you select a specific product in the image of the plan of the SEC, the workshops, sections and TRM are activated, participating in the current period of time in the repair of the midrange from the composition of this product (for example, these shops, sections and TRM are highlighted in the plan). When you select any of these workshops, sections and TPMs, the identification data of the midrange product with which the current repair work is being carried out are displayed on the screen. By setting the MF of interest, one gets on the screen a display of the current situation on this MF (the degree of completion of the work, the complexity, the executors of the work, the ratio with the planned dates, etc.). Based on the analysis of this information, for each TPM, site, workshop, and general repair center in general, an assessment is made of the current situation regarding the repair of a particular product and the midrange included in the products, control actions are generated, and through the corresponding work management workstations, message codes are issued containing instructions on necessary adjustment of the organization of work.

Visual monitoring of the current progress of work at the TRM, in the premises of sections and workshops, in auxiliary rooms and in the supporting services of the SRC is carried out using remotely controlled digital video cameras installed at the corresponding observation points in the rooms and in the transitions. The set of video cameras, each of which scans the sections of the SSC assigned to it, combined using the SSC information network (see Fig. 3) and connected to the central control system computer, form the video surveillance subsystem of the SSC. Information from the video cameras via the information network enters the control center, where it is displayed on the control monitors and on the screen (depending on the current situation) and is analyzed by the administrator of the control center on duty. This increases the safety level of the SSC and the efficiency of personnel management.

The specified construction of the SSC (see figure 1, figure 2 and figure 3) allows you to effectively carry out a full repair cycle of complex technical products (including military hardware systems) with the restoration of health and resource of these products. An enlarged diagram of the technological process of restoration repair of products in the claimed SEC is shown in Fig.3.

The implementation of the full technological cycle of product repair restoration (Fig. 3) as part of the declared SSC is based on the creation and application of a full set of production shops and sections, auxiliary units and services, as well as life support systems of the SSC, which are the functional components of the SSC. All rooms are equipped with the necessary equipment to perform repair processes of functional groups of component parts of products according to figure 1. All premises are united in a single production and technological system by transport and technological walkways and passages in accordance with the design of the structure in which the SEC is located. The identification information readers and remote-controlled digital video cameras installed in the premises of the workstation, as well as installed in control places, are connected to the ACS information network and connected to the control center of the SSC, which contains (at least) the central control system computer with the screen and control video monitors connected to it.

The identifiers are installed on the component parts of the product moved within the SSC, replaceable sets of technological equipment and sets of materials, tools and spare parts, as well as on the personnel of the SEC. In the interaction of identifiers with readers of identification information, control is provided of the current location of objects moved to the SEC (including SSC personnel), protection of the SEC premises from unauthorized access, control over the use of the property of the SEC and the overall performance of the SEC as a whole is increased.

The automated control system in the technical solution according to patent RU No. 2491186 (prototype) implements the solution of several groups of functional tasks:

1) situational management of work in the production rooms of the SEC for the repair of mid-range military hardware;

2) management of integrated debugging of repaired weapons and military equipment and their acceptance tests at a test site;

3) management of the work of the set of mobile repair and diagnostic complexes 4.0 (starting from the formation of tasks for carrying out the assigned work on repairing the weapons and military equipment samples at their places of deployment and ending with the return of the airborne systems to their permanent location as part of the SEC);

4) monitoring the technical condition of the weapons and military equipment at their locations and information support for the operations of military personnel using the remote access terminals 5.0.

The solution of the complex of these tasks provides overall management of the technical readiness of the territorial group of weapons and military equipment assigned to the SEC as controlled objects. In this regard, the control system of the SSC according to the patent RU No. 2491186 (prototype) is referred to as the automated technical readiness management system (ACS TG) of the controlled grouping of weapons and military equipment.

The undoubted advantages of the SSC patent RU No. 2491186 (prototype) are:

1) a comprehensive solution to the problems of ensuring the required level of technical readiness assigned to the SEC of the territorial arms and military equipment group;

2) adaptability to various types of weapons and military equipment that go into repair (by dividing the technological equipment of production sites into basic and replaceable sets);

3) effective information support of all types of work based on the use of IED and integrated situational work management.

Along with this, the SEC according to patent RU No. 2491186 (prototype) has a number of significant drawbacks that are most important when repairing anti-aircraft missile systems (SAM) and anti-aircraft gun-missile systems (SAM), which include anti-aircraft guided missiles (SAM). The main disadvantages of the prototype are:

1) the impossibility of maintenance and repair of rocket launchers, the work with which should be carried out in specially equipped rooms (capable of reducing the consequences of emergency situations, which can be when working with explosive products);

2) lack of conditions for training and training of operational and repair personnel of weapons and military equipment;

3) lack of efficiency in managing the preparation of mobile RDKs for the performance of assigned tasks;

4) reduced performance under adverse external influences.

The purpose of the claimed technical solution is to eliminate the disadvantages of the prototype. The composition and functional relationships of the components of a multifunctional center for maintenance and repair (MCTR) is shown in Fig.4. All the components of the ICTR are combined into a single system using the interface lines and interact under the control of the automated control system of the TG, the functions of which in the ICTR are expanded compared to the prototype. As shown in figure 4 and figure 5, the MCTR is based on the use of the SSC according to patent RU No. 2491186. At the same time, in order to ensure the stability of the SSC under external adverse influences (in particular during a special period), the production rooms of the SEC in which repairs of electronic equipment are carried out (in particular, the premises where work is carried out on the components of the military hardware 1.1, 1.7 and 1.9 - see figure 1) shielded from external electromagnetic fields. All production and auxiliary rooms of the SEC are airtight, and the ventilation and air conditioning system (which is part of the SSC life support system) provides for air filtration and the creation of excess pressure in the premises to prevent contaminated external air from entering the SEC premises.

The life support system of the SRC includes autonomous power and energy supplies (for example, a diesel power plant with a fuel supply) and autonomous water sources (for example, an artesian well or water tanks).

The set of mobile RDKs, which is part of the SSC (see Fig. 6) in the initial state is connected using interface cables into a single local area network (LAN RDK), which provides control of mobile RDKs using an automated process and resource management system (ACS PR) of repair and service located in one of the RDK (in RDK-7 in Fig.6 and Fig.7).

The specialization of the work and functions of the main types of mobile RDK included in the set of Fig.6, is illustrated in Fig.7.

The local computer network of the RDK kit is connected through the ACS PR to the interface network of the SSC (Fig. 7). With this connection, information is exchanged between the automated control system of the TG, which is part of the SSC (Fig. 2) and the ICTR as a whole, and the automatic control system of the set of mobile RDKs (Fig. 2, Fig. 6 and Fig. 7). Due to this, tasks for performing the assigned work are directly transferred from the automated control system of the TG, on the basis of which the automatic control system of the operational area provides operational staffing of all airborne systems for the assigned work (taking into account the type of military hardware, the technical condition, type and content of the assigned work, the completeness of the operational spare parts at the place of deployment of the military hardware sample and other).

The prototype does not provide for the possibility of training the repair and maintenance personnel in the rules for the effective maintenance and repair of mid-range armament and military equipment products both in the SEC and at the places of deployment of the armament and military equipment samples. The MPTR provides for these purposes a training center 6, which (as shown in Fig. 8) includes:

1) classrooms 6.1 for the development of technologies for working with IEDs, equipped with automated places connected by an interface highway;

2) lecture room 6.2, equipped with intellectual teaching aids;

3) classroom 6.3. equipped with simulator complexes for serviced weapons and military equipment;

4) classrooms 6.4 for mastering work with automated control and diagnostic systems and repair equipment;

5) a training room 6.5 for training mobile RDK personnel.

All automated training equipment is integrated into a local computer network connected to the automated control system of the training center (ACS UTC) 6.6. In turn, the control system of the UTC 6.6 is connected by an interface line to the automatic control system of the TG 3. The specified structure and information links of the UTC 6 (Fig. 8) provide high-quality and comprehensive training for the repair personnel of the SSC, RDK personnel (field repair crews) and operational personnel (combat crews) IWT samples. Two-way information communication between the automated control system of TG 3 and the automatic control system of UTTS 6.6 provides the operational replenishment of the control system of the UTTS 6.6 with up-to-date operational, repair and training documentation. Operational information on the results of staff training and training is received from the ACS of the UTs in the ACS of the TG, on the basis of which data on the composition and qualifications of repair personnel and operating personnel are constantly updated. This provides an increase in the efficiency of the ICTR as a whole.

To ensure the possibility of maintenance and repair of anti-aircraft guided missiles (SAM), which are part of the repaired and serviced weapons of the air defense system such as air defense missile systems, air defense missile systems, air defense missile systems, the missile repair center (missile launcher) 7 is additionally introduced into the ICTR of figure 4. 7. Structural diagram of the repair point SAM 7 is shown in Fig.9. An enlarged diagram of the technological process of repairing missiles is shown in Fig.10. Due to the specifics of missiles, as objects of maintenance and repair (due to their explosion hazard), missile launcher PR 7 is located as part of the ICTR in a separate structure, geographically remote from the main building of the SEC 2. The missile defense missile system 7 (see Fig. 9) includes production and technological sections, ensuring the implementation of the technological process of repairing missiles 10. All production sites are equipped with technological workplaces according to the profile of the work performed. At the same time, the workstations of the PR missile launcher (as well as the TRM SRC in the prototype) include automated workstations integrated into the local computer network of the automated control system (ACS of the PR SAM) 7.9, which is connected by a two-way interface line to the TG ACS (see Fig. 9). This ensures the operational management of work in the PR missile launcher 7 using the automated control system of the missile defense missile system 7.9, as well as centralized situational management using the control center, which is part of the automated control system of TG 3.

The construction of the missile launcher PR 7 is designed to ensure stability and taking into account the reduction of damage from possible contingencies caused by work with explosive products (SAM). The SAM repair station 7, like the SRC, has autonomous life support systems (including autonomous sources of electricity and energy supply and water supply) ensuring its increased stability and survivability. The introduction of PR missiles 7 in the ICTR (figure 4) provides the full scope of work on the maintenance of anti-aircraft missile defense systems, which could not be achieved using the prototype (RRC figure 2) according to patent RU No. 2291186.

The functions of the firing range as part of the ICTR as compared to firing range 2.13 as part of the prototype are expanded and provide all the necessary complex of work to ensure the deployment of repaired air defense and air defense products of the most complex structure, the final setup and their field tests. The structure of the landfill, which is part of the ICTR, is shown in Fig.11. The comprehensive testing ground (KIP) of Fig. 11, which is part of the ICTR, contains a set of automated test tools operating under the control of the corresponding ACS of the instrumentation, which is connected by an external interface line to the ACS of the TG.

Thanks to this, situational management of the works at the training ground and the necessary informational support for the ongoing deployment, configuration and testing of repaired as part of the ICTR air defense systems of various complexity (including air defense systems) are provided.

Thus, the claimed technical solution allows you to create a holistic multifunctional centers for maintenance and repair (MCTR) of air defense weapons of various complexity. The ICTR data contains all the previously indicated advantages of the SSC according to the patent RU No. 2491186 (prototype), but have additional positive qualities that are absent in the prototype.

Thanks to the implementation of new components and new functions as part of the ICTR, a new technical result was achieved, namely:

1) a full range of maintenance and repair work is carried out on the most complex air defense air defense systems containing anti-aircraft guided missiles and other explosive products;

2) operational training and retraining of maintenance and repair personnel is provided, on the basis of which the efficiency of the work performed both as part of the SRC, PR missiles and landfill, and at the locations of deployment of controlled air defense air defense weapons;

3) provides increased efficiency in the preparation of a set of mobile RDK for departure to the place of work (due to the organization of information interaction between the automated control system of the TG and the automatic control system of the PR and due to the management of the preparation of mobile RDK for the assigned work under the control of the automatic control system, also through appropriate training and training repair crews in the training center);

4) ensuring higher stability and survivability of the ICTR under conditions of external adverse factors (due to the screening of critical production areas from exposure to external electromagnetic fields, due to the introduction of overpressure filtering and ventilation units into the composition of the life support systems of the SEC and PR missiles, as well as autonomous means of electric and energy conservation and water supply).

Claims (4)

1. A multifunctional center for maintenance and repair (ICTR) of weapons and military equipment (IWT) air defense (air defense) and aerospace defense (EKO), which includes a stationary repair center (RRC), created on the basis of a production building, in which the production and technological components of the SEC are functionally interconnected during the implementation of the through technological cycle of product repair in the form of workshops and sections, the composition of which is determined by the composition of the groups of components of the products being repaired and types of work on them, including a workshop for fault detection, disassembly, assembly and adjustment of products, a workshop for repairing electromechanical components for products, a workshop for repairing mechanical components for products, a workshop for repairing hydraulic components, a workshop for repairing internal combustion engines , workshop for repairing power supplies, workshop for repairing electronic equipment, workshop for repairing ventilation and air conditioning, workshop for checking and repairing instrumentation, workshop for repairing communications and topographic referencing equipment, a workshop for repairing the basic chassis and means of mobility of products, a workshop for repairing bodies and containers connected via power supply and utilities to the life support subsystems of the SSC, as well as a testing ground for comprehensive testing of products after repair and the control center of the SEC with the central part of the automated control system (ACS), all the components of the SSC are interconnected by passages and passages, the production and technological components of the SEC are workshops and Astki are equipped with technological workplaces (TRM) according to the profile of the technological operations carried out to repair component parts (MF) of products and include basic stationary technological equipment - specializing in TRM and an automated workstation for information support of the TPM operator actions (hereinafter referred to as ARM-I) ), consisting of a computer, a monitor, a feedback manipulator and an identification data reader, except for the AWS-I, which are part of the TRM, cars are placed in each workshop and section of the SEC audited workstations for remote control of work (ARM-UR), premises of workshops and sections are equipped with access restriction means, for example, in the form of sliding doors equipped with combination locks and identification data reading devices, at checkpoints of passages and passages connecting the main and auxiliary components of the SEC, workshops, sections, automated storage, life support systems, control center, identification readers are installed, in rooms, walkways and A remote control digital video camera, all peripheral workstations, including ARM-I and ARM-UR, identification data readers and digital video cameras through the information center of the SSC and communication equipment are connected to the central computer of the ACS located in the control center of the SEC, to the central the ACS computer in the control center of the SSC connects the screen for displaying the current situation and the control monitors of the video surveillance subsystem of the SSC, the replaceable components are located in the automated storage of the SEC You are equipped with TPM technological equipment, designed to adapt TPM to the specifics of repair of midrange from different types of products, as well as sets of materials, tools, spare parts and other property used in the repair of products in accordance with the repair documentation, for all types of property being moved within СРЦ in the process of repairing products, identifiers are installed that interact with the identification data readers installed in the control places of the СРЦ, as well as in the ARM-I and ARM-UR identifiers the cores are also located on the midrange from the composition of the items being repaired and from the composition of spare sets, on technological vehicles used in the SSC, and on the staff of the SEC, interactive electronic repair documentation is placed in the database of the central control system computer before starting work on repairing each next type of product ( IERD), with the help of which automated situational control is carried out for the implementation of all the works of the end-to-end technological cycle of product repair in the SEC, through Remote access channels to the central computer of the automated control system of the TG can be connected to remote access terminals located at the locations of the regular deployment of controlled arms and military equipment from the serviced territorial arms and military equipment and used to monitor the technical condition of the military hardware and equipment group, the SEC includes a set of mobile airborne vehicles in the initial state integrated with the help of interface cables into a single local area network (LAN RDK), providing control of mobile RDK using an automatic machine of an automated process and resource management system (ACS PR) for repair and maintenance located in one of the RDK, the LAN of the RDK is connected to the interface network of the SRC through the ACS of the PR, using this connection information is exchanged between the automated control systems of the TG and the ACS of the PR of the RDK set and operational staffing of all RDKs for the assigned work, characterized in that all the production rooms of the SRC are airtight, the rooms in which the maintenance and repair of electronic equipment and the composition of the air defense and air defense missile and defense systems, made shielded to protect equipment, equipment and personnel from exposure to external electromagnetic fields, the filter support system was added to the life support system of the SEC to provide excess pressure in the SEC premises and to prevent contaminated external air from entering these rooms, as well as means of autonomous power supply, energy saving and water supply. 2. ICTR according to claim 1, characterized in that it additionally introduced a training center (UTC), which includes training rooms equipped with automated teaching aids and simulators that are connected by an interface highway and connected to an automated control system (ACS UTC) with the formation of a unified local computer network UTC, and the ACS UTC is connected via an external interface line to the automated technical readiness management system (ACS TG), which is part of the RCC. 3. ICTR according to claim 1 or claim 2, characterized in that it additionally introduces an anti-aircraft guided missile repair point (PR SAM) located in a building separate from the SEC with increased measures of stability and to reduce possible damage from emergency situations, production units PR missiles are formed in accordance with the structure of the technological process for servicing and repairing missiles, equipped with technological workstations (TPM) and their workstations (similar to TPM from the SSC), all workstations are integrated into the local computer network of PR Z P and connected to an automated control system (ACS PR ZUR), which is connected to an ACS TG using an external interface line, and a life support system similar to the life support system of the SSC, which includes filtering and ventilation means for creating excess pressure, is introduced into the PR ZUR in the premises of the PR SAM, the means of autonomous power supply, energy supply and water supply, all the premises of the PR SAM, are airtight. 4. ICTR according to any one of claims 1 to 3, characterized in that the ICTR integrated testing ground for integrated weapons and military equipment, an electric and energy supply system, automated workstations for tuning, checking and autonomous testing of component parts are included in the ICTR integrated test site IWT, equipment for the comprehensive tuning of IWT samples, equipment for creating a phono-target and interference environment, a range of run tests and verification of navigation equipment with a test track included in this range, all of which are automated All the means of these components of the integrated test site are interconnected by interface lines with their direct connection via an external interface line to the automated control system of the TG or by connecting them to the automated control system of the integrated testing ground (ACS KIP), and the automatic control system of the control instrument through the external interface highway is connected to the automatic control system of TG .

Images