SU583443A1 - Device for locating faults - Google Patents

Description

(54) TROUBLESHOOTING DEVICE

Claims (3)

The invention relates to automation and off-site technology and can be used in automatic troubleshooting devices in technical objects. A known system for recognition from the state of the control object, comprising the blocking of a recognizable vector (binary code of control results) and matching vectors, long-term and operative memory, arithmetic and analyzing blocks, an indication unit l. With the help of this system, the state of the object is determined for which the matching vector with a given recognizable vector has the greatest sum of zero coordinates. . The disadvantage of this system is its great complexity, as well as the fact that for each recognizable vector it indicates only one of the possible states of the object. Other conditions possible with this recognizable vector are not indicated, and a comparative assessment of the probabilities of these possible conditions is carried out, as a result, the search time for a non-direct object is increased. A device for monitoring the correctness of electrical connections in radio electronic equipment, a pulse generator, a control unit, switching units, pulse counters, a coincidence unit, a printing device is known. This device is used to determine the galvanic connection table in the monitored installation. 2. A disadvantage of this device is the impossibility of determining defective nodes during non-galvanic communication between the tested points of an object (for example, in mechanical devices). The closest in technical essence is a troubleshooting device comprising, in series, a common descrambler, a comparison unit connected to a memory unit and a display unit, a control unit and a pulse generator. 3 .. However, this device does not allow finding the faulty nodes, the outputs of the switches can not be measured, and also to take into account the combinations of the faulty nodes in the checked circuit. The aim of the invention is to expand the field of application of the device. YES, a sequentially connected pulse counter, connected to a pulse generator, a decoder and a display unit, a key block, a normalization unit, an adder and an analog-koa converter, whose output is connected to the display unit, are entered into the device. In the drawing, a structural diagram of the device is presented. The device contains a pulse counter 1, a decoder 2, a block of 3 keys, a block of 4 normalization, an adder 5, a block 6, a comparator, a block 7 of memory, a block 8 of indication, a generator of analog-code 9, a generator U of pulses and a block 11 management The device works as follows: From the output of counter 1, pulses are sent to the input of decoder 3 and, the discharge binary code of the hypothesis (the state code of the nodes of the object being checked), which as the pulses are received from the generator 10 pulses changes during operation of the device from the initial state of an OO .., O to the final state of 11 ... 1. The number of bits (n) of the counter 1 pulses is equal to the number of nodes of the object. The unit in the 4th category of the hypothesis code corresponds to the faulty state of the 1st node, and the zero to the healthy state of the i-th node of the object. The number (n) of the decoder 2 is equal to the number of object nodes, and the number of columns m descramble {JaTOpa 2 is equal to the number of object parameters to be monitored (the number of signs of malfunction), 1-row and j-th column of the decoder 2 are connected by a diode, if the fault is 1- This node leads to the exit for the admission of the Jth monitored parameter of the object. At each operation cycle of the device (i.e., after each pulse is applied to the counter 1 pulses, the decoder 2 converts the input n-bit binary hypothesis code into the output m-bit binary code of the results of parameter control (matching vector) corresponding to the hypothesis under consideration which is fed from the output of the decoder 2 to the first input of the comparison unit 6. The second input of the side 6 of the comparison from the memory block 7 is supplied with the m-bit binary code of the control results (recognizable vector) obtained during the control of the test parameters When the codes of the matching and recognizable vectors coincide, a matching signal is generated in the comparison block 6. This means that the corresponding state of the object's nodes is possible with this recognizable vector. The coincidence signal from the output of the comparison block 6 is fed to the display block 8. At the same time, the code of the hypothesis (the output code of the counter 1 and the pulses, at which the match of the mapped and recognized vector occurred), is registered in block 8 of the indication. At the same time, the code of the hypothesis from the output of the pulse counter 1 is fed through the block 3 of keys to the input of block 4. In this case, if the hypothesis code in the i-th bit is 1 (which corresponds to a malfunction of the I-th node), the {-and key opens, and a voltage (Uj) appears at the I-th output of the normalization block 4, proportional to, where QI -, -, t and PI is the probability of failure of the {-th node. If O is in the 1st code discharge of the hypothesis, then i is the key closed, and at the i-th output of normalization unit 4, the voltage is zero {V {O), the voltage from the n outputs of normalization unit 4 is fed to N inputs of the adder 5, which summarizes these voltages. The total voltage at the output of the adder 5, which is a function of the hypothesis probability, is fed to the input of the analog-to-converter converter into the corresponding digital code. This code is fed to display unit 8 where, in the presence of a coincidence signal at the output of comparison unit 6, it is registered together with the code of the corresponding hypothesis. The coincidence signal from the output of the comparator unit 6 is also fed to the control unit 11: which at the same time turns off the voltage pulser Yu from the pulse counter 1 for the time required for registering the codes in the display unit 8. After registration of the codes, pulses from the pulse generator Yu are again fed to the counter 1 pulse of the hypothesis until the appearance of a new change in the coincidence signal on the block g. The process repeats until all hypothesis TEDD bits (pulses 1 counter outputs) are 1. Thus, the proposed device allows you to view all possible states of the nodes of the object being checked, and in the display unit to record the codes of all Those States (faults), which are possible with a recognizable result of monitoring the parameters of the object, as well as information about the probabilities of these states, which allows you to quickly find and fix a malfunction in the object, the invention it contains a serially connected decoder, a comparison unit connected to the memory unit and the display unit, the control unit and the pulse generator, in order to expand the field of application of the device, B; S 7 W / V pulse counter connected to the pulse generator, the decoder and the display unit, the key block, the rating unit, the adder and the analog-code converter, the output of which is connected to the display unit. Sources of information taken into account in the examination: 1. Author's certificate of the USSR No. 261780; Mcl. 2 6 About .115 / 46, 197О. 2. USSR author's certificate number 187144, Mkl. 2 G 01 R 31/02, 1965. 3. USSR author's certificate No. 238236, Mkl. F15 / 46., 1967.