SU1167619A1 - Device for predicting random events in engineering system - Google Patents

Abstract

1. A DEVICE FOR PREDICTING RANDOM EVENTS IN THE TECHNICAL SYSTEM, containing a random pulse generator, a clock pulse generator and a block of counters, characterized in that, in order to expand the area of application for systems with a temporary reserve and increase the accuracy of the device, it contains a block of models of system elements , the block of formation of signals of failures, the switch, m outputs of which are connected to tn inputs of the block of counters, the first input - to the first output of the block of formation of failure signals, the second and third outputs of which They are connected respectively to (t + 1) -th and (t + 2) -th inputs of the block of meters, n odd inputs of which are connected to the outputs of the random pulse generator, and n even inputs - to the n outputs of the clock generator, (n + 1) th . the output of which is connected to the second input of the switch, and (n + 2) -th - to the second input of the signal-forming unit. failure mode, to the third inlet of which the nth output of the pulse generator is connected, the second output of the block of models of system elements is connected to (yy1 + 3) th. input block counters. 2. A device according to Claim 1, characterized in that the block of models of the system elements contains two ZI elements, n-2 elements 4I and n-1 reversible counters, a summing input of the first reversible counter and a subtracting input (n-1) of the reversing (L A counter is connected to the outputs of the first and second nth ZI elements, respectively, the outputs of the 4I elements are connected to the opposite inputs of adjacent reversible meters, the first inputs of all the ZI elements and 4I are odd inputs of the block, the second are even, the third inputs are from O5 of the second element ZI, connected to 1 to the first outputs of the reversible counters, O) the second outputs of which, except for (n-1) -th | w1 of the reversible counter, are connected to the fourth inputs of elements 4I, the second output (n-1) -g.o of the reversible counter is connected to the third input the second ZI element is the first output of the block; the second input of the block is the output of the second ZI element. 3. The device according to Claim 1, which is based on the fact that the block for generating failure signals contains three elements 2I, a one-shot and an inverter, the output of the first element 2I is connected to the inputs of the one-shot, the second ele

Description

2I and the inverter, the code of which is connected to the first input of the third element 2I, the first and second inputs of the first element 2I are the first and second inputs of the unit, the third input 11676 19 whose house is the second inputs of the second and third elements 2I, and the outputs of the one-oscillator and the second and third elements 2I.

The invention relates to computing and can be used in the design, testing and research of complex automated and robotic systems in which temporary redundancy is applied.

The purpose of the invention is to expand -ab-; areas of application for systems with a temporary reserve and increasing the accuracy of the device.

Fig. 1 shows the functional scheme of the proposed device for predicting random events in the technical system of Fig. 2, block diagram of the technical system.

The device contains a generator of 1 random pulses, a multichannel generator of 2 clock pulses, a block of 3 models of system elements, a block of 4 generating system failure signals, a switch 5 and a block of 6 summing up counters.

The block 3 of models of elements of the system contains elements And 7.1-7.P, as well as p-1 reversible counters 8.1-8. P-1.

The unit 4 for generating the failure signals of the technical system contains three elements 2И 9,10 and 11, an inverter 12 and a one-shot 13.

Switch 5 consists of D-triggers 14.1-14.t, forming the shift register, and the elements 2I 15.1-15.t.

Block 6 contains summing counters 16.1-16.t + 3. Generator 1, which is a typical p-channel random pulse generator, produces pulses whose duration is a random variable distributed according to a given law. The duration of the generated pulses is proportional to the random residence time of the AJ, i f units, (Fig. 2) of the technical system in a working condition of the scientific research institute, and the pause between pulses is to the random recovery time of the units.

A multichannel generator of 2 clock pulses is designed to form sequences of pulses of a given frequency. At the outputs of generator 2, associated with a block of 3 models, clock pulses are generated with a frequency proportional to the performance of aggregates A.

In block 3, elements 7.1-7.p are models of system aggregates. Each reversible counter 8.18 .n-1. imitates the drive,, n-1. (figure 2). The outputs of elements 7.1-7. P are connected to the summing and subtracting inputs of the reversible counters 8, -18. П-1. At the first output of each reversible counter, zero-level signals are generated in cases where the contents of the counter become equal to a value proportional to the limiting capacity of the corresponding drive. In the remaining cases, a single signal is present at the first outputs of the counters. At the second output of each reversible counter, a zero level signal is generated when the contents of the counter are zero (the drive is empty) and a single level signal in the remaining cases.

The unit 4 for generating the failure signals of the technical system, together with the switch 5, are used to record the instants of system failure as a result of the exhaustion of the temporary reserve determined by the reserves in accumulators B.1-B-P-1.

The first trigger 14 of the shift register prior to the start of operation of the device is set to one, and the triggers 14.2-14.m are set to zero.

The counters 16.1-16.in are designed to register the flow of failures of the sietema, in the counter 16.t + 1 the total time of the system’s failure-free operation is recorded, in the account, the counter 16.t + 2 - the total time of system recovery, and the counter 16.t + 3 - a number proportional to the total operating time of the technical system. With the help of this device, the process of functioning of a technical system with a temporary reserve arising due to the creation of intermediate stocks in accumulators is modeled. The time reserve allows the user to spend a certain time on the restoration of the elements of the technical system that have failed to operate. In the proposed device, random flows of failures and restoration of models of system units connected with a single technological cycle are reproduced. After the occurrence of a failure of an aggregate equipped with a hopper (bin for products), the system remains operational due to the presence of intermediate stocks of semi-finished products. This occurs under the condition that the recovery of the aggregate will be completed before the stock of products manufactured by the aggregates is exhausted before the moment of occurrence failure and being in its storage. Otherwise, the system crashes. The device works as follows. The generator 1 generates a sequence of pulses and pauses of random duration. The pulses arrive at the first inputs of elements 4I 7.2-7.P-1 of block 3. The second inputs of elements 4I are supplied with a sequence of pulses from the outputs of the generator 2 clock pulses. The third and fourth inputs of elements And 7.1-7.P of block 3 receive blocking signals from the outputs of reversible counters 8.1-8.P-1. If on the first and third inputs of the ZI 7.1 element there are signals of a single level, meaning that unit A) is in a healthy state and drive B is not completely full, then pulses from the first output of generator 2 pass to the first input of the reversible counter 8.1. This corresponds to the flow of products from unit A to the accumulator Bj. The presence of a zero-level signal at the first input of the ZI element 7. 1 corresponds to the failure of the A / unit. Zero-level signal at the third input of the ZI 7.1 element — the full filling of accumulator B. products in the drive In | -not enters. The second bypass input of the reversible counter 8.1 through the second input of the logic element 4И 7.2 receives pulses simulating the removal from storage A of the product for processing on the second unit Ag. If on one of the inputs of the item. 4 and 7.2 there is a zero-level signal, which accordingly simulates either the failure of unit A, or the overflow of drive B, or the complete emptying of the first drive. B), then the pulses from the second output of generator 2 do not pass to the second input of the reversible counter 8.1, and thus the contents of accumulator B are not reduced. The pulses from the output of element 4И 7.2 are also fed to the first input of the reversible counter. This corresponds to the process of filling the accumulator B. with products processed at the second unit A. Signals arriving at the inputs of the reversing counters 8.3-8. P are formed similarly. For fixing the number The processed product in block 6 uses a summing counter 16.t + 3, to which impulses are sent from the output of the ZI element 7.P simulating the last unit AJ in the technical system. To generate a signal about the failure of the entire system, the second output of the reversible counter 8.p and the output of the generator 1 are connected to the first and second inputs of element 2I 9, the output of which is electrically connected to the input of the one-vibrator 13. When the signal at the output of element 2I 9 changes from a single value to zero one-shot 13 generates a pulse supplied to the second inputs of the elements 2I 15.1-15.t. This pulse is passed to the input of the block 6 by the element 2I 15.1-15.m of the switch 5, at the first input of which at a given moment of time there is a signal of a single level.

Each counter 16.1-16.m is assigned a specific time interval. The required counter is selected by the shift register signal of the switch 5, the output of which is successively supplied with a unit level signal when pulses from the generator 2 of the clock pulses arrive at the synchronous inputs of the D-flip-flops 14.1-14.m.

Thus, in the 16.116 .m meters, the moments of failure of the technical system are recorded, which corresponds to the cessation of the flow of the output A, g products.

The signal from the output of element 2I 9 is fed to the first input of element 2I 10 to fix the total operating time of the technical system and through the inverter 12 to the second input of element 2I.11 to register the total time of system downtime. At the second inputs of the element 2I 10 and the element 2I 11 receives a sequence of pulses that set the time scale. In the summing counter 16. accumulates the number of pulses proportional to the total system downtime, and in the summing counter 16.t + +1 - the total uptime of the technical system.

As a result of processing the statistical data accumulated in the summing counters of block 6, the following numerical values of technical system reliability indicators are determined: the function of the failure flow parameter W (t), availability factor k and the coefficient simply kn of the system, taking into account the time backup. . The failure stream parameter function is determined by the formula

statistical evaluation of the value of CO (t) on the i-M time interval

accumulated in the 1st counter the number of system failures; specified number of implementations of the system operation process

the duration of the i-ro interval of the operating time of the system.

nt system readiness formula - ki

-r-k, k,

where k) is the contents of the counter 16.m + 1, k is the contents of the counter 16.m + 2. Coefficient simply systems are calculated by the formula

,, kj

Thus, using the proposed device, it is possible to predict random events in a technical system with temporary redundancy. La created in the process of functioning of the system, i.e. stocks of partially processed products in prom weft storages;

Phie. i

Claims (3)

1. DEVICE FOR FORECASTING RANDOM EVENTS IN A TECHNICAL SYSTEM, comprising a random pulse generator, a clock pulse generator and a counter unit, characterized in that, in order to expand the scope of application to systems with a temporary reserve and increase the accuracy of the device, it contains a block of model elements of the system , a fault signal generation block, a switch, m outputs of which are connected to m inputs of the counter block, the first input is to the first output of the failure signal generation block, the second and third outputs of which are are connected respectively to the (w + 1) th and (t + 2) -th inputs of the counter block, η odd inputs of which are connected to η outputs of the random pulse generator, and η of even inputs to η outputs of the clock generator, (items 4-1 ) th. the output of which is connected to the second input of the switch, and (n + 2) -th - to the second input of the signal-forming unit. failure, to the third input of which the nth output of the random pulse generator is connected, the second output of the block of models of elements of the system is connected to the (w + 3) th. the input of the counter block. 2. The device according to claim 1, characterized in that the block of model elements of the system contains two elements ZI, p-2 element 4I'i p-1 reversible counters, summing the input of the first reversible counter and subtracting the input of the (p-1) -th reverse the counters are connected to the outputs of the first and second ηth elements of the ZI, respectively, the outputs of the elements 4I are connected to the opposite inputs of the adjacent reversible counters, the first inputs of all the elements of the ZI and 4I are odd inputs of the block, the second are even, the third inputs are, in addition to the second element of the ZI, connected to the first out odes of reversible counters, the second outputs of which, in addition to the (n ~ 1) -th reverse counter, are connected to the fourth inputs of 4I elements, the second output of the (n-1) -g.o reverse counter is connected to the third input of the second ZI element and is the first output block, the second output of the block is the output of the second element ZI. 3 "The device according to claim 1, characterized in that the failure signal generation unit contains three elements 2I, a single vibrator and an inverter, the output of the first element 2Y is connected to the inputs of a single vibrator, the second OS 6191911 OS ment 2I and an inverter, the output of which is connected to the first input of the third element 2I, the first and second inputs of the first element 2I are the first and second inputs of the block, the third input of which are the second inputs of the second and third elements 2I, and the outputs are the outputs of the one-shot and the second and third elements 2I. X.