RU145063U1 - AUTOMATED DEVICE FOR CONTROL OF ELECTRICAL CIRCUITS OF COMPLEX TECHNICAL OBJECTS - Google Patents

Abstract

An automated device for monitoring electrical circuits of complex technical objects, containing a computer, a source of test effects, a meter for measuring electrical circuits and a low-voltage switch, while the code inputs for programmatically controlling a source of test effects, a meter for measuring electrical circuits and a low-voltage switch are connected to a computer via an interface line, the output of the source of test effects is connected to the input of the first field (matrix) of the low-voltage switch, the measuring circuit of the parameters of the electrical circuits is connected to the output of the second field (matrix) of the low-voltage switch, a technological harness is connected to the low-voltage switch to connect to the contacts of the controlled electric circuits of the monitoring object, characterized in that it also includes a high-voltage measuring device and a high-voltage switch, code inputs software control of which using the interface line are connected to the computer, the connection points of the high-voltage measuring Ibor connected to the input and output of the respective switching fields (matrices) high voltage switch for high voltage switch connected high-voltage technology harness for connection to contacts of controlled high-voltage electric circuit control object.

Description

The technical solution relates to the field of instrumentation, in particular, to technical means for controlling the quality of electrical circuits (internal installation) of complex technical objects, including weapons and military equipment.

Known devices for monitoring the electrical circuits of technical objects, including software control equipment, software-controlled sources of test signals, software-controlled switches and process cables (harnesses) for connecting to the contacts of controlled electrical circuits. Examples of well-known technical solutions are the installations according to patents RU 2208806, RU 78952, as well as the installation described in the article: S. Karpov “Expansion of the range of controlled objects for testers of printed circuit boards with a contact device” (Technologies in the electronic industry, 2012, No. 8 , p. 72).

Known devices provide control of the integrity and resistance of electrical circuits between the terminal contacts (connection points) of these circuits or sections of branching circuits, insulation resistance between disconnected circuits, as well as the operation of active elements (for example, relays) when applying control signals to control circuits.

Closest to the claimed device is a device for monitoring wired installation and printed circuit boards according to the patent RU 78952, taken as an analogue to the claimed technical solution.

The disadvantages of the analogue are:

1) the impossibility of reliable control of high-voltage electrical circuits;

2) the technical complexity of the device when monitoring complex installation, containing several hundred or more points of connection to electrical circuits (which will require the use of several tens of functionally complex measuring modules, shown in Fig. 2 in the description of the analogue).

The technical result of the claimed device is to simplify the technical implementation of the control of electrical circuits of complex technical objects containing a large number of electrical circuits with connection points of up to several thousand and including high-voltage electrical circuits.

The specified technical result is achieved by introducing into the device an additional switch for connecting the contacts of high-voltage circuits and the corresponding standard program-controlled measuring instruments.

The principle of operation of the claimed automated device is illustrated in FIG. 1, FIG. 2, FIG. 3. The device includes a computer 1, to which, using the interface line 2, the inputs of the code-based program control of the source of test influences 3, the parameter meter for electrical circuits 4, the low-voltage switch 5, the high-voltage measuring device 6, and the high-voltage switch 7 are connected . In this case, the output of the source of test effects 3 is connected to the input of the first field (matrix) of the switch 5, the input of the meter of parameters of the electrical circuits 4 is connected to the output of the second field (matrix) of the low-voltage switch 5, the connection points of the high-voltage measuring device 6 are connected to the input and output of the switching fields (matrices) of the high-voltage switch 7. A technological harness 8 is connected to the low-voltage switch to connect to the contacts of the controlled electrical circuits of the monitoring object 9, and to the high-voltage switch 7 a high-voltage technological harness 10 is connected for connecting to the contacts of the controlled high-voltage electric circuits of the control object 9.

Before using the device for its intended purpose, after installing and connecting all the components according to FIG. 1, the appropriate software is installed in computer 1, with which it is implemented

 automated control of all processes of monitoring the parameters of the electrical circuits of the control object 9. The software package (software) is common to all types of control objects. After installing the software package, a table of electrical connections of the object 9 to be controlled is entered into the computer's memory. The composition of the table includes the positional designation of the contacts of each branched electrical circuit of the control object, while for each section of the electrical circuit (for each pair of electrically connected contacts) indicate the criteria parameters (the maximum allowable value of the circuit resistance, the maximum allowable response time of the active elements, the minimum allowable resistance value isolation, etc.). The criterion parameters also indicate the value of the parameters of the test actions (for example, the value of the test voltage supplied when measuring the insulation resistance).

After loading into the memory of computer 1 of the data of the table of electrical connections and criteria parameters, the contacts of the checked electrical circuits of the control object 9 using a technological harness 8 are connected to the switch 5.

The operation of the installation of figure 1 when checking the integrity of the electrical circuit and the correct connections is as follows.

From the computer 1 through the interface bus 2, commands are received to the switch 5 by means of which the contacts of the beginning of the electric circuit and the end of the monitored section of this circuit are connected to the source of test influences 3 and / or to the parameter meter of electric circuits 4, as explained in Fig. 2 . In the case of monitoring electrical circuits with active elements (for example, a relay), the switching element K1-1 of the first matrix of the switch 5 connects the output of the test influences source 3 to the beginning of the electric circuit containing the controlled part of the active element (in the indicated example, the relay coil). The switching element K1-2 of the second matrix of the switch 5 connects the second end of the electrical circuit of the object 9 with the indicated relay coil (the control part of the active element of the controlled circuit) to the body of the source of test effects 3. The switching element K1-3 of the third matrix of the switch 5 connects the input measuring instrument of parameters of electric circuits 4 to the beginning of an electric circuit with an actuating element (in this example, a pair of contacts of a controlled relay in the control object 9, working to close the circuit or break chain). The switching element K1-4 of the fourth matrix of the switch 5 connects a common contact (housing) of the parameter meter of the electrical circuits 4 to the end of the electric circuit with the actuating element. Each matrix of commutator 5 (similarly, commutator 7) represents an independent (electrically isolated from others) switching field that performs programmatically controlled connection of a given contact of the monitoring object to the corresponding input (output) of device 3 or 4. After the processes are completed connecting the source of test actions 3 and the meter of the parameters of the electric circuits 4 using the switching elements of the matrices of the switch 5 to the control and executive electric circuit of the object 9 (see Fig. 2) according to the program to on-trol from the output of the meter of electrical circuits 4 to the computer 1 receive codes of the current values of the parameters (resistance) of the Executive electrical circuit R (t). After a programmed delay from computer 1 at time t _0, through the interface bus 2, the command of test effects 3 is sent to the source of test effects 3 to issue a test effect to the control circuit of the object 9 with the given parameter values U (t ₀ ), which ensure that the active part of the active item. The actuation of the executive part of the active element and the response time is determined by measuring the resistance parameters R (t _i ) using meter 4. For example, when the relay contacts are closed in the initial state, this moment is determined by a sharp decrease the value of the resistance of the actuator circuit

R (t _i ) << R (t _o ).

When the relay contacts open in the initial state, the actuation of the active part of the active element (relay) is determined by a sharp increase in the resistance value of the controlled circuit

R (t _i ) << R (t _o ).

The value of the time interval (t _i -t _o ) from the moment of sending from the computer 1 a command to the source of test influences 3 to the moment t _{i of} determining, with the help of a parameter meter of electric circuits 4, the actuation of the executive part of the active element of the controlled circuits of object 9 (closing or opening relay contacts - respectively) is a controlled parameter of electrical circuits of complex technical objects, along with monitoring the integrity of circuits, the absence of false connections and short circuits, as well as insulation resistance values between the chains of the object of control 9.

The integrity of the electrical circuits and the resistance values of the sections of the electrical circuits is controlled by the device of Fig. 1 without using the source of test influences 3, as well as the first and second matrices of the switch 5. By command from the computer 1 through the interface highway 2 to the switch 5, the common contact of the meter of electrical parameters is connected circuits 4 through the technological harness 8 to the beginning of the controlled electrical circuit of the object 9. In general, the controlled electrical circuit can be multi-link ( connect several contacts on different connectors as part of the control object 9) and have branches. In accordance with the table of connections entered into the memory of computer 1, the switch 5 (using another switching matrix) sequentially connects to the input of the meter 4 intermediate points (links) of the controlled electric circuit and the end points of the branches of this circuit. The values of resistance R _ij measured using a meter 4 of each section of the circuit are compared with the maximum allowable values previously stored in the memory of computer 1 as part of the data table of the electrical connections of the object of control 9. When the measured values are within the tolerance for each section of the circuit

the controlled circuit is considered to be working. If the tolerance is exceeded, the identification data of the circuit section defect containing the designation of the contacts in the structure of the object 9, between which the defect is detected, and the defect parameters (R _ij ) are entered into the computer memory.

After the control of one of the electrical circuits is completed, the switch 5, on a command from the computer 1, connects to the meter 4 the contacts of the next circuit, the data of which are listed in the electrical connection table of the control object 9.

After completing the control of the last electric circuit from the table of electrical connections of object 9, previously stored in the memory of computer 1 before starting the operation of the device of Fig. 1, the device goes into operation in the mode of monitoring the presence of false connections, short circuits and the value of insulation resistance between disconnected (not electrically connected according to the connection diagram of the object 9) electrical circuits of the object 9.

The operation of the device of Fig. 1 in the mode of monitoring the presence of false connections, short circuits between circuits and monitoring the value of insulation resistance is as follows.

Using one of the switching matrices of the switch 5 (for example, the third, see Fig. 2), according to the instructions from the computer 1, based on the data of the connection table, the measuring input of the meter 4 is connected to one of the points of the controlled circuit of object 9. Using another switching matrix of the switch 5 (for example, the fourth, see figure 2) another contact (common or housing) of the meter 4 is connected immediately to the points from the composition of all other electrical circuits of the object 9, except for the circuit connected to the measuring input. At the same time, for each electric circuit disconnected (not electrically connected) with the controlled circuit, it is enough to connect to one point. After connecting to the points of all disconnected circuits (not belonging to this monitored circuit) using meter 4, the resistance value (R _x ) is measured between this circuit and other circuits. The measured value (R _x ) according to the program is compared with the criterion value (R _out ) entered in the data of the connection table. If the measured value of the insulation resistance is small

(R _x << R _out ),

this means the presence of a short circuit (false connection) between this electrical circuit and other electrical circuits of the object 9.

When a sign of a circuit is detected (R _x << R _out ), the switch 5, by commands from the computer 1 (based on the data on the contacts of the connected circuits), starts to disconnect the circuits alternately until a result appears (R _x ≥R _out ), which means there are no short circuits between this controlled circuit and the remaining (not disconnected from the common contact of the meter 4) combined electric circuits of the control object 9. After this, by commands from the computer 1, using the switch 5, the circuits previously disconnected from the common contact of the meter 4 are connected in turn. After each connection, the measured resistance value R _x is fixed between the monitored circuit and the combined remaining circuits. In the event that after connecting the next previously disconnected circuit, the condition of closure (R _x << R _out ) is detected, then this circuit is again disconnected and a defect is fixed on it, consisting in the presence of a circuit between these two (disconnected according to the circuit) circuits. Similarly, a check is performed on all other previously disconnected electrical circuits.

In the event that no short circuits between this monitored electrical circuit and the other connected circuits are detected, then the insulation resistance value R _{x is} measured between this circuit and the remaining circuits disconnected with respect to it. According to the measurement results, if a result is obtained , then the finding of the insulation resistance value in the tolerance is fixed. Parameter is included in the criterion data for each monitored circuit in the connection table, loaded into the computer's memory before starting the control procedure for electrical connections of this type of control object 9. Continuing the sequence for each electrical circuit listed in the connection table of object 9 before starting operation of the device of FIG. 1, receive a complete list of control results and detected defects. If faults are detected, the defects are removed, and then a repeated procedure is performed to check for the absence of faults and to control the insulation resistance values. The test is considered complete if, when monitoring the insulation resistance values of each electrical circuit with respect to the other combined electrical circuits from the table of electrical connections of object 9, the measured insulation resistance values satisfy the tolerances set in the data of the connection table for each circuit.

It should be noted that the application of the group method of monitoring insulation resistance between each individual electrical circuit and the combined remaining (disconnected according to the product circuit) electrical circuits simplifies the technical implementation of monitoring the presence of faults in the composition of complex technical objects containing up to 1000 and more electrical circuits.

Measurement of insulation resistances by the considered method should be carried out with the application of the corresponding value of the test voltage U _ucn . For low-voltage electrical circuits, insulation resistance testing is performed at test voltage U _ucn no more than (100V 250V). Accordingly, the meter 4, the switch 5 and the technological harness 8 should be designed for the specified value of the test voltage. However, in modern complex technical facilities (in particular, in weapons and military equipment), along with low-voltage electrical circuits (for which insulation resistance values are tested at test voltages of not more than 100 V ÷ 250 V), high-voltage electrical circuits are included (verification of values insulation resistance for which they are produced at test voltages up to 1.5 kV).

In the traditional approach, in this case, the meter 4, the switch 5 and the technological harness 8 must meet the requirements of operation with a test voltage of up to 1.5 kV. However, low-voltage circuits must thus still be tested at lower values of the test voltage (U _isp B ÷ 100 = 250). Based on this, the meter 4 should provide for the possibility of software setting the values of the test voltage over a wide range (for example, up to 1.5 kV), which leads to its significant rise in price. In addition, the cost of a high-voltage switch (as is known from the prior art) is ten or more times higher than the low-voltage switches that are similar in the number of switched circuits. Therefore, the implementation of the device based on traditional technical solutions, known from analogues, to provide such a device for monitoring mixed (low-voltage and high-voltage electrical circuits of complex technical objects) with the inevitable use of a high-voltage measuring device 4 as a circuit parameter meter, as well as full-scale ( the entire composition of the electrical circuits of the control object 9) of the high-voltage switch of electric circuits (as a switch 5) and high-voltage technology biological harness will lead to an increase in the cost of the device for monitoring mixed electrical circuits by about an order of magnitude (at least several times).

Analysis of complex technical products (in particular, armaments, military and special equipment) has established that the proportion of high-voltage electrical circuits in the total number of monitored electrical circuits of such products usually does not exceed 10%. With this in mind, the high voltage measuring device (high voltage tester) 6, high voltage switch 7 and high voltage technological harness 10 are additionally introduced into the claimed device of FIG. 1, with the help of which a combined method of combined control of low and high voltage measuring circuits of complex technical products is implemented.

When implementing this method, at the first stage, the integrity and resistance values of all electrical circuits are checked (both low-voltage and high-voltage) and faults are detected, as well as the insulation resistance values are tested at low levels (within 100 V ÷ 250 V) of the test voltages according to the considered earlier procedure. After identifying and eliminating all defects (including possible short circuits in high-voltage electrical circuits), disconnect the process harness 8 from the test object 8, which was used to control under the low-voltage test voltage, and connect the high-voltage process harness 10 to the high-voltage circuits of the test object 9.

The procedure for monitoring the insulation resistance values of the high-voltage electrical circuits of facility 9 (having undergone preliminary control under the low-voltage test voltage) is carried out as follows.

According to the instructions from the computer 1, based on the data of the connection table, one of the contacts of the high-voltage measuring device 6 is connected to one of the monitored high-voltage electric circuits of the monitoring object 9 using the high-voltage switch 7 and the high-voltage technological harness 10 (see Fig. 3). The remaining high-voltage electric circuits of the test object 9 are connected (combined) to the second contact of the high-voltage measuring device 6. After connecting, the high-voltage measuring device 6, on command from computer 1, supplies the set (high-voltage) value of the test voltage to the connected circuits and monitors the value of the leakage current characterizing the resistance value insulation between the given high-voltage circuit and other circuits (including the building of facility 9). The procedure is repeated for each chain. If an insulation resistance value below the permissible value is detected by any circuit, the circuits are disconnected from the structure of the connected (combined) circuits - until pairs of electrical circuits are found between which there is a reduced insulation resistance value (this procedure is similar to that previously considered for monitoring insulation resistance low voltage electrical circuits). Identified defects and numbers of the corresponding electrical circuits are recorded in the memory of computer 1 for use in the repair of facility 9. After eliminating the defects, the control procedure is repeated until the required insulation values of the high-voltage electrical circuits are restored to each other and with respect to the building 9.

The application of this method, when the high-voltage measuring device 6, the high-voltage switch 7 and the high-voltage technological harness 10 are used only when controlling the insulation resistance under a high test voltage ("breakdown control"), can significantly reduce the requirements for the measuring device 4 and low-voltage switch 5, t .e. reduce the complexity of their technical implementation and their cost. This allows you to get additional useful result.

Thus, the claimed device of FIG. 1 and the method for monitoring electrical circuits of complex technical products (in particular, weapons, military and special equipment with the presence of high-voltage electrical circuits in them) provides the claimed technical result:

1) increasing the reliability of control of high-voltage electrical circuits of complex technical products;

2) simplification of the technical implementation and cost of automated installations for monitoring mixed (low-voltage and high-voltage) electrical circuits of complex technical products (including weapons, military and special equipment).

The industrial implementation of the claimed device and the method of monitoring mixed (low-voltage and high-voltage) electric circuits of complex technical products implemented with its use is based on the use of standard equipment known from the prior art.

As computer 1, typical serial personal computers of domestic and foreign manufacture can be used, having the necessary equipment and a standard interface (Ethernet, USB), which allows implementing a standard interface highway for connecting standard serial devices.

As a source of test effects 3, any program-controlled power supply with the required output voltage adjustment range and a standard interface compatible with computer 1 can be used.

As a low-voltage switch, for example, the Agilent 34980A multifunctional switching unit with Agilent 34922A modules (or similar equipment from other companies) can be used.

As a measure of the parameters of the electrical circuits 4 can be used, for example, a milliometer digital GOM-82 company Good Will Instrument Co, as well as serial digital multimeters with the corresponding metrological characteristics.

As the high-voltage switch 7 can be used switches of the company Cytec corp. with modules like HXV / 8 and similar devices of other companies.

As a high-voltage measuring device 6, a high-voltage tester GPI-725 from Good Will Instrument Co., combining a breakdown installation and an insulation resistance meter, can be used.

Technological harness 8 and high-voltage technological harness 10 can be implemented using cable products used in products 9 for the implementation of regular low-voltage and high-voltage electrical circuits.

Thus, the industrial feasibility of the claimed device and implemented by the device control method is obvious.

Claims (1)

An automated device for monitoring electrical circuits of complex technical objects, containing a computer, a source of test effects, a meter for measuring electrical circuits and a low-voltage switch, while the code inputs for programmatically controlling a source of test effects, a meter for measuring electrical circuits and a low-voltage switch are connected to a computer via an interface line, the output of the source of test effects is connected to the input of the first field (matrix) of the low-voltage switch, course measuring electric circuits connected to the output parameter of the second field (a matrix) of low voltage switch for low voltage switch connected Technology harness for connection to terminals of electric circuits controlled control object, wherein by the fact that a high-voltage measuring device and a high-voltage switch are additionally introduced into it, the code control inputs of which are connected to a computer via an interface line, the connection points of the high-voltage measuring device are connected to the input and output of the corresponding switching fields (matrices) of the high-voltage switch, to the high-voltage a high-voltage technological harness is connected to the switch to connect to the contacts of controlled high-voltage electric circuits KTA control.