RU2554658C1 - Method of automated monitoring of electric circuits of complex technical products - Google Patents

Abstract

FIELD: instrumentation.

SUBSTANCE: method is based on the use of automated software-controlled monitoring system which comprises PC with interface bus for connection of the switch with at least two independent switching fields and the measuring device by means of which parameters of electric connections between contacts of the product sockets and resistance of isolation between independent electric circuits of the product are measured. Channels of switch fields are connected to contacts of the product sockets by means of two process bundles and replaceable adapters. Note that full check of electric connections of products is divided into partial procedures of test of connections of alternately connected product sockets with reference to other alternately connected sockets electrically connected to this socket accepted as reference one for each partial test procedure.

EFFECT: considerable decrease of the switch and volume of process bundles that allows to provide complete monitoring of complex electric connections using compact portable devices in conditions of confined working space.

6 cl, 1 tbl, 1 dwg

Description

The invention relates to the field of instrumentation, in particular to methods and devices for quality control of electrical circuits (internal wiring and cable connections) of complex technical products, including weapons, military and special equipment.

Known methods for monitoring electrical circuits of complex technical products and devices that implement these methods.

Known methods are based on the use of program-controlled circuit switches, which using technological harnesses connect the contacts of the controlled electrical circuits of the product with a measuring device and, under the control of software control equipment (for example, a computer), connect the controlled electrical circuits of the product to the measuring device with the switching program incorporated in it . Using a measuring device, the values of the resistance of the measured electrical circuits and the insulation resistance are measured, the measured values are compared with the tolerance values in the computer memory, and on the basis of this, the integrity of the controlled electrical circuits is determined, the permissible insulation resistance values between adjacent circuits are detected, erroneous connections (short circuits) between the circuits are detected , as well as the lack of necessary connections.

An example of well-known technical solutions is the method implemented in the installation monitoring system Test 9110-VXI (Informtest Holding, www.inftest.ru) and in devices according to patents RU 83851, RU 111683, RU 115499.

The closest technical solution adopted as a prototype in relation to the claimed method is the method implemented in the installation control system Test 9110-VXI (Holding "Informtest).

The advantage of the prototype is the ability to control all the electrical circuits of a complex technical product with a large number of contacts of the connection sockets (up to 10,000 contacts or more) with a single connection of the device to the controlled product. Thanks to this, the duration of the control process of all electrical circuits of complex technical products is reduced.

The disadvantages of analogues, including the prototype, are:

1) the complexity of technical implementation and high cost. To create an installation that provides control of products with a large number of contacts connecting to electric circuits up to 10,000 contacts or more, the volume of the equipment of the switches can occupy several instrument racks. To connect the device to the product requires the use of a bulky design of technological harnesses with the appropriate number of cores (for example, more than 10,000). In the case of monitoring several types of products at one installation, the volume of technological harnesses and their cost increase in proportion to the number of types of controlled products;

2) the complexity of the design of control installations according to the known method, which does not allow the use of similar technical solutions for operational work on repairing components of weapons, military and special equipment (WWE) at the locations of deployment of WWE samples. If it is necessary to monitor and diagnose the electrical circuits of rack-mount and cab-mount installations (with the number of connection points up to 10,000), it is impossible to place a bulky control system containing several equipment racks and the corresponding number of bulky process connection cables in the limited working space of the cab of the component part of the VVST sample.

The purpose of the claimed technical solution is to simplify the technical implementation of monitoring and diagnostics of electrical circuits of complex products with a large number of connection points (including in a limited work space) - while ensuring the necessary quality and reliability of monitoring and diagnostics.

The technical result from the implementation of the claimed technical solution is:

1) the compactness of devices that provide monitoring and diagnostics of electrical circuits of complex technical products with a large number of connection points (up to 10,000 or more);

2) providing the ability to control electrical circuits of rack-mount and cab-mount installation of components of WWI samples with a limited amount of internal working space;

3) cost reduction (up to 10 times or more) of hardware implementation of control procedures and diagnostics of electrical circuits of complex technical products.

Implementation of the claimed method is carried out using an automated system for monitoring and diagnosing electrical circuits (ASKD EC), shown in figure 1.

The ASKD EC includes a computer 1, in the memory of which, before the system began to operate, a set of private contact tables of each standard connector of the monitored product with the electrically coupled contacts of other connectors of the product are stored. Computer 1 through an interface highway 2 is connected to a measuring device 3 and switch 4. Switch 4 contains several autonomous switching fields (switching matrices), while the number of switched channels in each matrix must be on the largest number of contacts of any of the standard connectors of the product under control . The common outputs of each field (matrix) of the switch are connected to the corresponding contacts of the measuring device. As a measuring device, a combined device can be used, providing measurements of the resistance values of the controlled electrical circuits of the product and monitoring the insulation resistance (for example, similar to the device used for similar circuits in the prototype according to application No. 2013129132). When controlling electrical circuits with active (executive) elements in the ASKD of figure 1, a switch with four independent switching fields (matrices) should be used, as in the prototype.

The channels of the first and second field (matrix) of the switch 4 are connected to the first 5 and second 6 technological harnesses ending in sockets 7 and 8 for connecting to the contacts of the sockets 13-i of the controlled product.

To ensure the versatility of ASKD figure 1, the technological harnesses 5 and 6 with connectors 7 and 8 are unchanged. The connection of fixed technological harnesses 5 and 6 to the contacts of electrical circuits of controlled products of different types is carried out using transition devices - interchangeable adapters 11. Each adapter (11-1, 11-2, etc.) includes interconnected mating connector of the technological harness 9, 10 (which are generally identical) and mates (12-1, 12-2, etc.) of the standard connectors of the controlled product. The length of the technological harnesses 5 and 6 should provide the ability to connect them to the most remote connectors 13 of the controlled product. The connectors in the adapters 11 are connected using short chains, much shorter than the length of the technological harnesses 5 and 6. This ensures an economic effect when controlling several types of products.

The number of interchangeable adapters 11, in the maximum case, does not exceed the total number of standard connectors in each type of controlled product. At the same time, only two adapters are used for monitoring - one (11-1) for connecting the first technological harness 5 to the corresponding reference connector (13-1) of this private connection table, and the second (11-2) - for connecting the second technological harness 6 to others (13-2, ..., 13-i, ..., 13-n) to the standard connectors of the product 15. The second technological harness 6 is connected to the other standard connectors of the product 15 in turn in accordance with the monitoring procedure being implemented and the monitoring task being solved (like this explained below).

The implementation of the method of monitoring the parameters of the electrical circuits 14 and the diagnosis of faults in the electrical connections of a complex technical product 15 with the applied ASKD EC of FIG. 1 is carried out as follows.

Before starting the control process, an iterative control control program (which is common for all types of controlled products 15) and a set of removable private connection tables (individual for each type of controlled products) are entered into computer 1. The set of private connection tables reflects the whole topology of electrical circuits 14 of the controlled product 15.

Each private connection table reflects a fragment of the electrical connections of the product 15 and contains a description of the electrical connections of each standard connector 13 of the product 15 with other connectors (13-i) electrically connected to this connector. The connector 13, relative to which the connections to the other connectors 13-i of the product are described in the private connection table, is the reference during the phased implementation of the control procedure for each private connection table. The private connection table also contains the tolerance values of the resistance parameters of each tested electrical circuit, tolerances on the insulation resistance values between the circuits, identification data of interchangeable adapters for connecting to the reference connector 13 and other standard connectors (13-i) of the monitored product, instructions for connecting the paired connectors and other connectors (not electrically connected to this reference connector) of the product 15.

The contents of the private connection table are explained in the following table 1. The form of the table is determined by the basic software of the ACDS EC.

According to the instructions displayed on the monitor screen from computer 1 on the basis of the corresponding (first in order) private connection table, the first technological harness 5 is connected with the replaceable adapter (11-1) to the first standard connector (13-1), which is the reference for monitoring electrical circuits within this private connection table.

Using another interchangeable adapter (11-2), according to the instructions on the basis of a private connection table (see example - Table 1), the second technological harness 6 is connected to the first (13-2 paired standard connector of the monitored product.) Run the program for automatic control of circuit parameters, under the control of which the channels of the first matrix of the switch 4 through a removable adapter (11-1) and the first technological harness 5 connect a contact (for example, contact "1" - see table 1) of the reference connector 13-1 to one of the contacts of the measuring device 3. Using the second comm the utilization matrix of the switch 4 through a removable adapter (11-2) and the second technological harness 6, connect the corresponding contact of the conjugate connector (13-2) connected to the ASKD EC to the second contact of the measuring device 3. Electrically connected to the reference connector (13-2) An example of a private connection table is pin 15 of connector 13-2.

Using a measuring device 3 under the control of computer 1, measure the value of parameter “a” of the measured electric circuit (a _i ) and compare the measured value with the tolerance (a ₁₅ ) established in the private connection table for this monitored circuit. The control results are entered into the protocol in the memory of computer 1 and go on to a similar procedure for controlling the next circuit, connecting the next contact (in our example, contact “25”) of the conjugated connector (13-2).

The control procedure of the parameters of the electrical circuits is continued until the exhaustion of the contact numbers in the conjugate connector, connected (according to the private connection table) with this reference connector (13-1) of the controlled product.

After completing the control procedure for the standard connections of the contacts of this reference connector (13-1) with the corresponding contacts of the connected mated connector (13-2), they proceed to the procedure for monitoring the presence of short circuits and false (abnormal) connections. By standard connections are meant the connections between the contacts of the standard connectors 13 of the product 15 provided by the electrical circuits 14 according to the electrical circuit of the product 15.

Using the first matrix of the switch 4 under the control of computer 1, through the first technological harness 5, all the contacts of the reference connector 13-1 are connected to the first contact of the measuring device, which (according to the private connection table) have regular connections with the paired connector 13-2.

Using the second matrix of the switch 4 under the control of computer 1, through the technological harness 6 are connected to the second contact of the measuring device 3 those contacts of the conjugate connector 13-2, which should not have electrical connections with the contacts of the reference connector (according to the private table of connections and the electrical circuit of the product 15) . Using a measuring device 3 under the control of computer 1, the insulation resistance is measured between the combined contacts of the standard electrical circuits of the reference connector 13-1 and the contacts of the paired connector 13-2 electrically independent of the standard circuits. In the absence of short circuits, they proceed to the procedure for monitoring the insulation resistances between the standard electrical circuits of the reference connector 13-1. If faults are detected using the second matrix of computer 4 under the control of computer 1, the previously connected contacts of the conjugate connector 13-2 are alternately disconnected and the insulation resistance is measured in this way between the independent contacts of the connected connector 13-2 remaining in the connected state and the standard electrical circuits of the reference connector 13- one. In the absence of a short circuit, the previously detected short circuit of the disconnected contact of the conjugated connector 13-2 is fixed and the defect is repaired. The procedure is repeated until all existing faults are removed. After elimination of the defects, they proceed to the procedure for monitoring the insulation resistance of the standard circuits of the reference connector 13-1.

Using the first matrix of the switch 4, one of the contacts of the standard electrical circuits of the reference connector 13-1 is connected to the first contact of the measuring device 3 (as in the control procedure for standard connections). Using the second matrix of the switch 4 to the second contact of the measuring device 3 connect all the contacts of the conjugate connector 13-2, except for contacts having regular electrical connections with this contact of the reference connector 13-1. The insulation resistance of the electrical circuit of a given contact of the reference connector 13-1 is measured with respect to the remaining standard electrical circuits of this reference connector. Enter the result of measurements of the insulation resistance in the protocol. Using the first matrix of the switch 4 under the control of computer 1, based on the private connection table, the previously connected contact of the standard electrical circuit of the reference connector 13-1 is disconnected and the contact of the next regular electrical circuit of this reference connector 13-1 is connected. Using the second matrix of the switch 4 disconnect from the second contact of the measuring device 3 those contacts of the conjugate connector 13-2, which belong to the next checked regular electrical circuit of the reference connector 13-1. Repeat the procedure for monitoring the insulation resistance for the next regular electrical circuit. This procedure is repeated until the insulation resistance test of all standard electrical circuits connecting this reference connector 13-1 to this paired connector 13-2 is completed.

After the quality control of the electrical connections of this connector 13-1 with this paired connector 13-2 is completed, the results of the control are entered into the protocol and the defects detected are fixed, the technological harness 6 is disconnected from the paired connector 13-2 and connected to the next one using the corresponding interchangeable adapter 11-3 mated connector 13-3, the contacts of which have electrical connections with the contacts of this reference connector 13-1. Instructions on the re-installation of the second technological harness 6 and on the replacement of the replaceable adapter are issued according to the program to the computer screen 1 on the basis of information contained in a private connection table. After confirming the connection to the next mated connector 13-3, the previously reviewed control cycle is repeated, including the procedures for monitoring the presence and parameters of standard electrical connections between the reference connector 13-1 and the next paired connector 13-3, monitoring for abnormal connections (short circuits) and monitoring the resistances isolation between the standard electrical circuits connecting this reference connector 13-1 with the next paired connector 13-3. The control results are each time recorded in the control protocol. The control procedure is controlled by computer 1 based on the current private connection table describing the set of electrical connections of this reference connector 13-1 with other standard connectors 13-i having electrical circuits with a reference connector 13-1 in accordance with the electrical circuit of the product 15.

After checking the quality of the electrical connections of this reference connector 13-1 with all the standard connectors 13-i of the product 15, with which (according to the private connection table) there should be regular electrical connections provided by the electrical circuit of the product 15, they check for the abnormal connections of this supporting connector 13 -1 with the rest of the connectors.

Using the first matrix of the switch 4 under the control of computer 1, all the contacts of this reference connector 13-1 are connected to the first contact of the measuring device 3. According to the instructions issued on the monitor of computer 1 in accordance with the private connection table, the second technological harness 6 using the appropriate adapters 11, alternately connected to the standard connectors 13-n, which should not have electrical connections with this standard connector 13-1. Using the second matrix of the switch 4 under the control of computer 1, all the contacts of the connected independent connector 13-n are combined and connected to the second contact of the measuring device 3. Under the control of computer 1, the resistance is measured and the absence of abnormal connections (short circuits) is determined.

In the absence of abnormal connections, the technological harness 6 is re-connected to the next independent connector 13-n and the indicated control procedure is carried out.

When a short circuit is detected, the contacts of the independent connector 13-n are alternately disconnected using the second matrix of the switch 4 and contacts that have abnormal connections with the electrical circuits of the reference connector 13-1 are detected. After eliminating the identified defect, the control procedure is continued until the bypass of all standard connectors 13 of the product 15 is completed.

After completing the considered cycle of checking the quality of electrical connections of connector 13-1, the next private connection table is activated in the memory of computer 1, in which the corresponding connector 13-k from the standard connectors of the electrical circuits 14 of product 15 is defined as a reference connector. Under control of computer 1, repeat the above quality control cycle of electrical connections, but according to the next private connection table as applied to the next reference connector 13-k.

To reduce the total duration of the quality control of electrical connections (electrical circuits 14) of the product 15 as a whole, when controlling electrical circuits for the next reference connector 13-k (according to the next private connection table), all circuits whose quality has already been checked during the control according to the previous ones are excluded from the checks private connection tables.

The control process is completed after conducting control on all private connection tables, which together cover all cross-connections between all standard connectors 13 of electrical circuits 14 of product 15. At the same time, all possible abnormal connections between the connectors are covered by the test.

The considered procedure provides a solution to the whole range of tasks of monitoring and diagnostics of electrical circuits of complex technical products, as well as using the prototype. Unlike the prototype, to realize complete control of the product with a large number of controlled electrical connections (for example, with the number of connector pins up to 10,000 or more), you do not need a huge number of complex and bulky process cables and complex switches to the specified number of channels to connect all the contacts of the product. In the claimed technical solution, it is enough to have 2 technological cables 5 and 6 and a set of interchangeable adapters 11. The structural and technological implementation of interchangeable adapters 11 (including two connectors interconnected by short electric circuits) is much simpler and cheaper than the corresponding number of technological cables with traditional connection provided in the known analogues and prototype. This advantage is even more significant in the case of using the claimed device for monitoring several types of products, because (in the case of using analogues) for each type of product will require its own individual set of process cables.

The increase in the duration of control in the case of application of the claimed technical solution pays off by reducing the cost of the control system. In addition, if damage to electrical circuits is eliminated (for example, combat damage to an inside rack and inside cabin installation of weapons and military equipment), the place of damage can be localized visually. In this case, only the damaged part of the electrical connections is subject to inspection, which will lead to a reduction in the amount of necessary checks. At the same time, the compactness of the control unit, which will be convenient to use in the limited space of the standard room of the product being repaired, will be an essential advantage.

Thus, as follows from the considered device and the principle of operation of the control system that implements the claimed method, the claimed technical result is implemented, namely:

1) the creation of a compact control device that provides complete quality control of electrical circuits of complex technical products (for example, with the number of connected contacts up to 10,000 or more);

2) the ability to control the electrical circuits of the internal rack and the cabin installation of the components of military hardware in a limited working space (due to the use of 2 process cables instead of dozens of cables - in the case of analogues and prototype);

3) reducing the cost of hardware implementation of control with an adequate quality of control (by reducing the number of switch channels by tens of times, replacing bulky and expensive process cables with more compact and cheap replaceable adapters);

4) the ability to quickly switch from monitoring one type of product to controlling another type of product (instead of replacing complex cable systems, it is enough to use another set of compact interchangeable adapters).

Technical implementation of the claimed technical solution is carried out using equipment (measuring device 3, switch 4, computer 1) and materials (technological cable bundles based on serial cable products) known from the prior art and identical to those used in the implementation of the prototype and other analogues.

Claims (6)

1. A method for monitoring electrical circuits of complex technical products, based on the use of a control device that includes a computer and a measuring device and a switch connected to it via an interface line, including connecting the switch channels through technological harnesses to the contacts of the electrical circuits of the controlled product, measuring the parameters of electrical circuits using measuring instrument under computer control and the assessment of the quality of electrical circuits according to the measurement results, differing in those m, that when monitoring complex technical products containing complex electrical connections with more than two connectors, a switch with two independent switching fields is used, a constantly connected technological harness is connected to the channels of each switching field of the switch, while the number of channels of each independent switching field of the switch and the number of The electrical connection circuits of each of the two technological harnesses permanently connected to them must correspond to the maximum number of of the facts of any of the standard connectors of the monitored products, before the start of the control procedure, a set of private connection tables of each standard connector of the monitored product with other standard connectors having electrical connections with this connector, which is accepted as the reference one for monitoring using this private connection table, is placed in the computer’s memory in the composition of the private connection table includes criteria parameters to which the controlled electric circuits and insulation resistance between with independent electric circuits, complete control of the quality of electrical connections and troubleshooting of the entire product is carried out in stages, at each next stage, according to the instructions from the computer, they connect the first technological harness to the standard connector of the product, which is defined as a reference according to the verified private connection table, the second technological harness as directed from a computer, based on a private connection table, they are alternately connected to other standard product connectors using a measuring device and computer-controlled mutators control the quality of the connected electrical circuits and the quality of insulation resistance, fix the detected defects in the computer’s memory, upon completion of the electrical connection control procedure using one private connection table, activate the next private connection table in the computer’s memory, reopen the first technological harness to the next regular connector, which is the reference for the control of this particular table of connections and repeat the above control procedure to the quality of the electrical circuits of the product according to the current private connection table, upon completion of the control procedures for all private connection tables using a computer, the final control results are displayed on the monitor and printer, if defects are found, they are eliminated and re-checked according to the private connection tables, within which defects. 2. The method according to claim 1, characterized in that for each type of product interchangeable adapters are preliminarily made, comprising mating connectors of the technological harness connected between the same contacts and mating parts of the corresponding standard connectors of the monitored products, connecting the technological harnesses to the standard connectors of the product using adapter plug-in adapters according to the instructions on the computer monitor based on the data given in the corresponding private connection table, while for checking different product types use the same technological harnesses, the length of which provides access for connecting the switch fields to the remote product connectors. 3. The method according to claim 1, characterized in that during the control for each subsequent (after the first) private connection table, the control of those connections that have already been checked according to the previous private connection tables for the previous connectors used as reference are excluded. 4. The method according to claim 1, characterized in that it does not carry out control of erroneous connections of this reference connector with connectors that are not electrically connected according to the connection scheme with this connector, if such control was carried out earlier according to the set of control procedures according to the previous private connection tables. 5. The method according to claim 1, characterized in that not all connectors of the electrical connections of the product being monitored, but only connectors of the damaged part of the product, known on the basis of a priori information about the nature of damage to the product according to the results of a visual inspection or functional monitoring the performance of the relevant components of the product. 6. The method according to claim 1, characterized in that when controlling electrical circuits with active controlled elements, two additional independent fields of the switch are introduced into the switch, each of which is connected to the corresponding technological harness.