RU2688946C1 - Automated control device for extended multicore cables - Google Patents

Abstract

FIELD: monitoring and measuring equipment.SUBSTANCE: invention relates to control and measuring equipment, in particular to devices and methods of controlling electric circuits of extended multicore cables used for connection of isolated from each other independent components of complex engineering systems, including systems of weapons and military equipment. Automated control device for extended multi-core cables includes a computer, to which a measuring instrument and a switch with two independent switching fields are connected through an interface bus. Process switch harness is connected to switch channels to connect device to near-end connector of controlled cable. One end of the process wire is connected to the output of the measuring device, the second end of which with the plug-in plug is intended for connection to the connector of the remote end of the monitored cable – to control integrity of the cable cores.EFFECT: simplified implementation of quality control of multi-core cables of large length, when design implementation (sealing in the ground, in shelters, et cetera) does not allow to combine both ends of cable for its control.4 cl, 1 dwg

Description

The invention relates to the field of instrumentation technology, in particular to devices for monitoring the quality of long-haul cable connections used to connect the autonomous components of complex technical systems (CTS) geographically separated from each other, including weapons systems and military equipment (IWT).

Known devices for monitoring electrical circuits of complex technical products include switches with a set of switched channels for connecting contacts of monitored electrical circuits to measuring devices, instruments for measuring parameters of electrical circuits and insulation resistance between circuits, a computer for controlling the process of controlling electrical circuits and sets technological harnesses for connecting the switch channels to the control points of electrical circuits.

Examples of known devices are: “Device for the continuity of wires of multicore cables” (RU 83851), “Automated system for monitoring electrical connections” (RU 111683), “Device for controlling installation” (RU 115499), “Automated system for monitoring and diagnostics of electrical circuits technical products "(RU 2569911).

The closest analogue in relation to the claimed technical solution is the automated control system for patent RU 2569911, adopted for the prototype.

The prototype device includes a computer, a measuring device, a switch with two independent switching fields and two technological wiring harnesses that connect the channels of the switching fields to the connectors of extensive electrical circuits, including the connectors of cable connections.

Monitoring the integrity of electrical connections and the absence of short circuits between insulated electrical circuits using a prototype device is carried out under computer control, the memory of which is preliminarily entered into the table of connections between connectors of the test object, to which technological wiring harnesses are connected.

The advantage of the prototype device is to provide the possibility of automated control of the integrity of areas of complex electrical connections in confined spaces at regular places of the component parts (in cabins, in compartments of van bodies and container bodies) of complex technical systems, in particular, HVT HF systems.

The disadvantage of the prototype device is its technical complexity and high cost of implementing control of long stranded cables that are used to connect autonomous components of complex technical systems, which are geographically remote from each other, including weapons and military equipment (for example, cables connecting the radar station and command center of an anti-aircraft missile system) . In such cases, for the use of a prototype device, it is necessary to use multi-strand process harnesses, the length of which will be comparable or exceed (taking into account the conditions of laying on the ground) the length of controlled long cables, and the cost of such harnesses may exceed the cost of the rest of the equipment of the prototype device.

The goal of the claimed solution is to constructively simplify and cheapen the implementation of quality control of extended multi-core cable connections used in the structure of the JTS (in particular, IWT systems) for connecting the autonomous components of such JTS geographically remote from each other. This ensures control of the integrity of the electrical circuits (conductors) of extended cable connections and control of the absence of short circuits between the conductors of cable connections without disturbing the design position of the monitored cables as part of the JTS (placement in special channels, pipes, etc.).

The structural diagram of the claimed device shown in the drawing.

The device includes a computer 1, to which a measuring device 3 and a switch 4, having two independent switching fields, are connected via the interface bus 2. A technological harness 5 terminated with a connector 6 is connected to the channels of switch 4. Technological harness connector 6 is connected to the near end 7 of the monitored long stranded cable 8. At the remote end of the monitored cable 8 there is a standard socket 9. The first output is connected to the _output 3 of the measuring device 3 the end of the process wire 10, the second end of the process wire 10 is connected to the plug-end 11, which is designed to connect to the connector 9 of the remote end of the monitored cable 8 during operation the device is in the mode of monitoring the integrity of the electrical circuits (cores) of the monitored cable 8 and is disconnected from the connector 9 when the device is operating in the mode of monitoring the absence of short circuits between the electrical circuits (cores) of the cable being monitored 8.

The first independent field switch 4 provides alternate connection (on commands from the computer 1 via a bus 2) switching channels connected to circuits process the harness 5, the measuring input _Rin By measuring device 3.

The second independent field of the switch 4 provides the connection of any set of switching channels (specified by commands from computer 1 via bus 2) to output To the _{output of the} measuring device 3 when the device operates in the control mode of absence of short circuits of the monitored cable 8 (control of insulation resistance).

When the device is operating in the integrity monitoring mode of the monitored cable 8, the second switching field of the switch 4 does not participate in the operation and does not connect the common contact K of the _common measuring device 3 to the electrical circuits of the technological harness 5.

каждой жилы кабеля 8, допуск на измерения сопротивлений жил ΔR, минимальное допустимое значение сопротивления изоляции R_из между жилами кабеля 8, а также значение сопротивления R_тп технологического провода 10 и значения сопротивлений цепей R_цж технологического жгута 5).When preparing the device for operation, the program for controlling the operating modes of the device, initial data of the monitored cable is entered into the memory of the computer 1 (description of the connection table of the contacts of the connector 7 of the near end of the cable 8 with the corresponding contacts of the connector 9 of the far end of the cable 8, nominal values of resistances

each conductor of the cable 8, the tolerance on the resistance measurement lived ΔR, the minimum allowable value _{of the} insulation resistance R between the conductors of the cable 8, and the resistance value R _m technological wire 10 and the resistance values R chains _tszh process harness 5).

The device works in two modes:

1) monitoring the integrity of the electrical circuits (conductors) of the monitored cable 8;

2) control of the absence of short circuits of the electrical circuits (conductors) of the cable being monitored 8 (control of insulation resistances between the cores of the cable 8).

Before starting operation of the device in the integrity monitoring mode of the monitored cable 8, a plug 11, connected at the remote end of the process wire 10, is installed on the connector 9 of the remote end of the monitored cable 8. This ensures that all contacts of the connector 9 are connected (short-circuited) through a plug 11 on technological wire 10. The second switching field of the switch 4 at the same time is disabled and is not involved in the work.

) и технологический провод 10 (характеризующийся известным калибровочным значением R_тп). Измерительный прибор 3 измерит результирующее значение сопротивления R_Σ замкнутой электрической цепи, которое будет характеризоваться суммой значений сопротивлений:Upon command from the computer 1 via the interface bus 2 switching of the first switch box 4 through process harness 5 to the connector 6 connects to the measuring input _Rin By measuring device 3 controlled by a first electrical circuit (conductor) controlled cable 8. As a result, between the output of the measuring device K _O 3 and the measuring input of this device forms a closed electrical circuit including the commutation field of the switch 4 and the core of the process harness (characterized by the known resistance K _W ), connected the core “i” of the monitored cable 8 (characterizing by unknown resistance

) and technological wire 10 (characterized by a known calibration value R _TP ). The measuring device 3 will measure the resulting resistance value R _{Σ of a} closed electrical circuit, which will be characterized by the sum of the resistance values:

Based on the known values of _Kj and R _tp computer 1 determines the current value of the resistance of the monitored core of the cable 8:

сопротивления этой жилы (на основе исходных данных в памяти компьютера 1) с учетом допуска ΔR:compares the value obtained with the nominal value

the resistance of this core (based on the original data in computer memory 1), taking into account the tolerance ΔR:

Condition (3) means the integrity of the tested electrical circuit of the monitored cable. If condition (3) is not met, this means a violation of the integrity (break) of the controlled circuit.

The computer 1 records the result of monitoring the integrity of the controlled «i-one" cable core in the memory and instructs the first field switching switch 4 for connection to the measuring input _Rin By measuring device 3 once «i plus 1" circuit (conductor) controlled cable 8. Process control continues until all cores of the monitored cable are searched 8. After that, computer 1 generates a monitoring result, which implies a conclusion about the integrity of all the monitored cable cores or about the presence of defects (breaks) and the need for repair A 8.

After completion of the core integrity monitoring mode of the cable 8, the plug 11 is disconnected from the connector 9 of the remote end of the monitored cable 8 and is not used when the device is in the control mode of the cores of the cable. All contacts of the connector 9 of the remote end of the cable 8 are disconnected from each other.

In fault mode the control computer 1 outputs through the interface bus 2 through the first switching field of the switch 4 on the connecting cable controlled first core 8 (as in the previous operation) to the measuring input _Rin By measuring device 3. Subsequently, the computer 1 via the interface bus 2 gives commands, in fulfillment of which the second switching field of the switch 4 connects all the other wires of the monitored cable 8 to the output To the _{output of the} measuring device 3. The measuring device 3, at the command of computer 1, via the interface bus 2 measures the insulation resistance between the first residential controlled cable 8 connected via the first field switching switch 4 for measuring input K _Rin measuring device 3, and the remaining conductors of the cable 8 connected via a second field switch switching 4 to yield K _O Meter 3 The measurement result of R _{out. i} is transferred to the computer and compared with the tolerance. If the measured value of the insulation resistance meets the established allowable value, then this cable core 8 does not have any short circuits with all other cable cores 8. Otherwise, this wire with other cable cores 8 occurs.

If a positive result (no fault), the computer 1 commands the switch 4 to disconnect these conductors by measuring input K _Rin measuring device 3 and connected to a measuring input K _Rin measuring device 1 with a first field switch switching 4 another cable controlled strands 8 . Following this, the computer 1 via a bus 2 commands the switch 4 on the cable 8 is disconnected this core (previously connected via the second switching field of the switch 4) on the output _O by measuring instrument 3. by le this insulation resistance is measured again connected between a controlled residential and other (connected to the output meter K _O 3) controlled cable cores 8.

Evaluation of the control result is made similarly to the previously considered case to control the insulation of the previous cable core 8.

If a positive result, the measurement input K _Rin measuring device 3 connects another lived controlled cable 8, which is disconnected from output K _O measuring device 3 and the process of insulation monitoring regular conductor in relation to other strands continues until a complete check of insulation resistance between the penultimate and last cores cable 8.

In case of detection of a short circuit of one of the tested wires “i” of the cable being monitored, it is necessary to establish which of the other cores is closed. For this purpose, previously connected by a first switching field this «i-fifth" core left connected to the measuring input _Rin By measuring device 3. Through the second field switching switch 4 on commands from the computer 1 successively cut off the remaining strands from the output meter K _O 3 After each disconnection, measure the insulation resistance between the “i-that” core and the remaining connected to the output To the _output conductors. The establishment of the fact of the normal value of insulation resistance after disconnecting the “i plus k” core will mean the presence of a short circuit between the cores “i” and “i plus k”. This can be additionally verified by disconnecting from the common contact K _{common of} all other conductors and connecting the conductor “i plus k”. After the discovery of a pair of closures between them, the process of monitoring closures between the other conductors proceeds in the considered manner.

Upon completion of the operation of the device in the second mode, computer 1 will generate information on the presence or absence of breaks (defects) in the wires, as well as on the presence or absence of short circuits between the conductors. This means that the device provides complete quality control of the monitored lengthy multicore cable, and also generates the necessary data for cable repair - when defects are detected.

In the process of control, the cable retains its design position (i.e., it can be in construction, laid in pipes, buried in the ground, etc.) and does not require dismantling to control it.

This creates an additional technical and economic effect from the use of this device.

In the case of the application of the prototype device for the considered purposes, it would be necessary to manufacture and use a cumbersome large-capacity technological bundle, the length of which should be commensurate with the length of the monitored long-stranded cable or exceed this length. In the case of the use of the claimed device instead of the harness is applied single-core technological wire 10.

The economic effect of this will be the higher, the greater the length of the monitored cable 8 and the more lived in the monitored cable 8.

Industrial implementation of the claimed device is carried out on the basis of the use of a typical computer, resistance meter and switch of electrical circuits, known from the prior art and similar used in the implementation of the device prototype. Technological harness is implemented on the basis of a combination of wires (similar to one of the technological harnesses used in the composition of the device prototype). As the technological wire can be used flexible wire of the required length from the nomenclature of wires produced by industry. For the connection of the process harness with different types of connectors of the monitored cables, interchangeable adapters (adapters) similar to those used in the prototype device can be used.

Thus, the claimed device, industrially implemented on the basis of equipment and materials known from the prior art, and provides the implementation of the claimed technical result, which consists in reducing the cost and ensuring the effectiveness of quality control of long stranded cables used in the composition of the CTS, including systems of weapons and military equipment.

Claims (4)

1. Automated device for monitoring extended stranded cables containing a computer and a measuring device and a switch connected to it via an interface bus, characterized in that the switch contains two independent switching fields, one of which provides alternate switching of input channels to the input of the measuring device and the second field switching provides the integration of the specified inputs of the channels and their connection to the output of the measuring device, the process harness is connected to the switch inputs, it ends plugged in to the near end connector of the monitored long stranded cable, an extended process wire is connected to the device, the proximal end is connected to the output of the measuring instrument, and a plug is connected to the remote end of the process wire and is connected to the connector on the remote end of the monitored long cable when monitoring the integrity of the cable cores, while in the memory of the computer, before starting the control procedure, an electrical connection table is placed Inonii controlled cable comprising compounds description contacts near and remote-controlled cable connectors, as well as the resistance values lived controlled cable and the insulation resistance between the conductors of the cable. 2. The device according to claim 1, characterized in that the connection of the process wiring harness to the near end connector of the monitored lengthy multicore cable is connected via an interchangeable adapter to ensure that different types of cable connectors are coordinated with the connector at the technology wiring end connected to the channels switch. 3. The device according to claim 1 or 2, characterized in that the remote end of the process wire is connected directly to the connector contacts of the remote end of the cable to be monitored, for example, using special clips, ensuring that all the contacts of this connector are closed at the end of the process wire. 4. The device according to PP. 1, 2 or 3, characterized in that when operating in the control mode of the circuit between the cores of the cable, the remote end of the process wire is disconnected from the connector pins at the remote end of the cable to be monitored, while all the contacts of the remote cable end are interrupted.

Images