RU2361277C1 - Device for determining optimum maintenance period of articles - Google Patents

Abstract

FIELD: physics; computer engineering.

SUBSTANCE: invention relates to computer engineering, particularly to control devices and can be used in scientific research and operating practice for determining optimum maintenance periods of articles and time required for carrying out maintenance. The device contains two adders, three multipliers, nine switches, five delay elements, an integrator, OR element, two dividers, non-linearity unit, timer clock, comparator and a subtractor.

EFFECT: increase in functional capabilities due to formation of output parametres in form of operational state time and maintenance time in the interval of a single maintenance cycle of an article.

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Description

The invention relates to computer technology, in particular to control devices. It can be used in scientific research and operational practice to determine the optimal terms for technical maintenance of products and time required to perform a set of maintenance operations. The optimization criterion is the maximum product availability factor.

Known devices [1, 2, 3], allowing to determine the periods of maintenance, ensuring the maximum possible readiness of products for use for their intended purpose. A common drawback of these devices is the limited informative capabilities, since they do not allow to obtain, as an output quantity, the time required for servicing the product corresponding to the optimal period of service.

The closest in technical essence to the claimed invention is a device [4], containing two adders, three multipliers, seven keys, three delay elements, an integrator, an OR element, two division blocks, a nonlinearity block, a time sensor, a comparator and a subtractor. Its disadvantage is limited informative capabilities.

The aim of the proposed technical solution is to expand the informative capabilities of the device. The goal is achieved by issuing as the output data the values of the operating time and the time required for the maintenance of the product, with the optimal frequency of its maintenance.

The process of servicing products is cyclical in nature. The average duration of the service cycle is determined by the following ratio:

or

Where

τ is the product service period;

- среднее время контроля работоспособности;

- average time for monitoring performance;

- среднее время проведения плановой предупредительной профилактики;

- the average time for planned preventive prevention;

- среднее время аварийно-восстановительных работ;

- average time for emergency recovery work;

P (τ) is the probability of failure-free operation of the product during time τ.

Value

is the duration of the maintenance process on the interval of one cycle.

The health control of the product is carried out in scheduled sessions with a period of τ. In this regard, in the time interval between control sessions, the product can be not only in a healthy state, but also in failure.

Therefore, there is a ratio:

Where

- среднее время работоспособного состояния изделия;

- the average working time of the product;

- среднее время пребывания изделия в отказе.

- the average residence time of the product in failure.

определяется по формуле:Value

determined by the formula:

If the results of the inspection show that the product is operational, then a planned preventive maintenance is carried out. If it turns out to be inoperative, emergency repairs will be carried out, as a result of which the operability will be restored. Thus, the process of functioning of the product is regenerative.

When carrying out operations of health monitoring, preventive maintenance and emergency recovery work, as well as when the product is in a state of failure, it cannot function as intended. The availability factor of the serviced product is determined using the following ratio:

It can be seen from (5) that the availability coefficient substantially depends on the service period τ of the product. Studies show that the function K _G (τ) for some (optimal) value of the period τ ^* has a global extremum. Deviations of the service period from optimal to smaller or larger values lead to a decrease in the availability factor.

In connection with the foregoing, the problem of determining the optimal period of maintenance of the product can be written as follows:

In the practice of operating a wide class of products (especially products operating in standby mode), an important characteristic is the coefficient of operational readiness. Its value for the current time is determined as follows:

where P (ξ) is the probability of failure-free operation of the product at time ξ. Wherein

Where

- длительность цикла обслуживания, определяемая соотношением (1), но при оптимальном значении периода τ^* обслуживания изделия;

- the duration of the service cycle, determined by the relation (1), but with the optimal value of the period τ ^{* of} service of the product;

- целое число циклов обслуживания, которое может быть проведено на интервале T_f=[0,t_f].

- an integer number of service cycles that can be performed on the interval T _f = [0, t _f ].

Taking into account (5) K _og (t) will be expressed by the following relation:

Here P (ξ) = exp {-λξ}, where λ is the failure rate of the product.

и

. Заявляемое устройство позволяет определять их, реализуя соотношения (2) и (4), и представлять в качестве выходных параметров.To plan the use of the product for its intended purpose, as well as maintenance work on the product, it is necessary to know the calculated values of the quantities

and

. The inventive device allows you to define them, implementing the relationship (2) and (4), and present as output parameters.

The proposed mathematical model can be implemented in hardware using the inventive device (see drawing).

The device contains: adders 1, 5; multipliers 2, 23, 26; keys 3, 14, 15, 17, 19, 20, 21, 22, 24; delay elements 6, 7, 11, 12, 18; integrator 8; element OR 9; blocks of division 10, 25; block of nonlinearity 4; time sensor 13; comparator 16; subtractor 27.

, T_f подается соответственно на 1, 2, 3 и 4 его входы.Before starting the operation of the device, the initial information: λ,

, T _f is fed to its inputs 1, 2, 3, and 4, respectively.

The device operates as follows

The time sensor 13 with a step Δτ sets in increasing order the sequence of possible values of τ _i , the period of technical maintenance of the product, τ _i = τ _i-1 + Δτ, where i = 1, 2, .... In the initial state, keys 3 and 14 are open, and keys 15, 17, 19, 20, 21, 22, and 24 are closed.

и передается через первый ключ 3 на первые входы первого умножителя 2 и интегратора 8. В интеграторе 8 эта функция интегрируется на интервале [0, τ_i]. При этом верхний предел интегрирования определяется значением сигнала τ_i, поступающего на второй вход интегратора 8 с выхода датчика 13 времени. Выходной сигнал интегратора 8, соответствующий, согласно (4), величине

, поступает на второй вход первого блока 10 деления и через третий элемент 11 задержки на информационный вход четвертого ключа 17. Сигнал τ_i с выхода датчика 13 времени подается также на второй вход второго 5 сумматора.The signal τ _i from the output of the time sensor 13 through the second key 14 and the OR element 9 connected in series is fed to the second input of the nonlinearity block 4, the first parameter of which receives the product parameter λ. In block 4 of nonlinearity, the function

and is transmitted through the first key 3 to the first inputs of the first multiplier 2 and integrator 8. In integrator 8, this function is integrated on the interval [0, τ _i ]. Moreover, the upper limit of integration is determined by the value of the signal τ _i supplied to the second input of the integrator 8 from the output of the time sensor 13. The output signal of the integrator 8, corresponding, according to (4), to

is supplied to the second input of the first division unit 10 and through the third delay element 11 to the information input of the fourth key 17. The signal τ _i from the output of the time sensor 13 is also supplied to the second input of the second 5 adder.

, поступающим на второй вход сумматора 1 с третьего входа устройства. Выходной сигнал

первого сумматора 1 непосредственно поступает во второй сумматор 5, где формируется, в соответствии с (1), значение длительности цикла обслуживания изделия

, а через первый элемент 6 задержки передается на информационный вход шестого ключа 20. Сигнал, соответствующий величине

, с выхода второго сумматора 5 передается непосредственно на первый вход первого блока 10 деления и через второй элемент 7 задержки на информационный вход седьмого ключа 21. В первом блоке деления 10 реализуется вычисление значения коэффициента готовности согласно (5), т.е.

. Полученный результат К_гi, с выхода первого блока деления 10 подается непосредственно на первый вход и через четвертый элемент 12 задержки на второй вход компаратора 16.In the first multiplier 2, the multiplication of the quantity P (τ _i ) and the difference (τ _pp -τ _av ) supplied to it from the second input of the device is realized. The resulting signal corresponding to the value (τ _pp -τ _av ) P (τ _i ), from the output of the first multiplier 2 is transmitted to the first adder 1, where the operation of summing with the signal

coming to the second input of the adder 1 from the third input of the device. Output signal

the first adder 1 directly enters the second adder 5, where, in accordance with (1), the value of the product service cycle duration is formed

, and through the first delay element 6 is transmitted to the information input of the sixth key 20. The signal corresponding to the value

, from the output of the second adder 5 is transmitted directly to the first input of the first division unit 10 and through the second delay element 7 to the information input of the seventh key 21. In the first division unit 10, the readiness coefficient value is calculated according to (5), i.e.

. The result obtained K _gi , from the output of the first division unit 10 is supplied directly to the first input and through the fourth delay element 12 to the second input of the comparator 16.

с выхода седьмого ключа 21 поступит на второй вход второго блока 25 деления и первый вход третьего умножителя 26, а выходной сигнал первого элемента задержки 6, соответствующий времени технического обслуживания τ^* _обс, через шестой ключ 20 поступает на первый выход устройства. В блоке 25 деления вычисляется целое число циклов обслуживания, которое может быть проведено на интервале времени T_f, т.е.

. Полученный результат передается в третий умножитель 26, где формируется сигнал, соответствующий произведению

и передается на второй вход вычитателя 27. В вычитателе 27 реализуется разность

и через схему ИЛИ 9 подается на второй вход блока 4 нелинейности. В блоке 4 нелинейности формируется сигнал Р(ξ) и через третий ключ 15 подается на второй вход второго умножителя 23. Выходной сигнал датчика 13 времени, задержанный пятым элементом 18 задержки и соответствующий оптимальному значению τ_i-1=τ^* периода технического обслуживания изделия, через восьмой ключ 22 поступает на третий выход устройства.In the comparator 16, the current K _gi and the previous K _gi-1 calculated values of the availability coefficient are compared. If it turns out that K _gi ≥K _gi-1 , then the control signal will appear on the first output of the comparator 16, as a result of which the time sensor 13 will give a new τ _{i + 1} value for the maintenance period and the whole cycle of calculations of K _g will be repeated, but with a new value period. If it turns out that K _gi <K _gi-1 , then the control signal will appear on the second output of the comparator 16 and will go to the enable inputs of the first 3, second 14, third 15, fourth 17, fifth 19, sixth 20, seventh 21, eighth 22 and the ninth 24 keys. Note that by the control signal of the comparator 16, keys 3 and 14 are closed, and all other keys are opened. As a result of this, the signal corresponding to the set value of the time T _f from the fourth input of the device through the ninth key 24 will go to the first inputs of the second division unit 25 and subtractor 27. The signal

from the output of the seventh key 21 will go to the second input of the second division unit 25 and the first input of the third multiplier 26, and the output signal of the first delay element 6, corresponding to the maintenance time τ ^* _obs , through the sixth key 20 is fed to the first output of the device. In the division unit 25, an integer number of service cycles is calculated that can be performed on a time interval T _f , i.e.

. The result is transmitted to the third multiplier 26, where a signal corresponding to the product

and transmitted to the second input of the subtractor 27. The difference is realized in the subtractor 27

and through the OR circuit 9 is fed to the second input of the nonlinearity block 4. In block 4 of the nonlinearity, a signal P (ξ) is generated and through the third key 15 is supplied to the second input of the second multiplier 23. The output signal of the time sensor 13, delayed by the fifth delay element 18 and corresponding to the optimal value τ _i-1 = τ ^* of the product maintenance period, through the eighth key 22 enters the third output of the device.

The output signal of the third delay element 11, corresponding to the average product operating time τ ^* _f , through the fourth key 17 is supplied to the second output of the device. The output signal of the fourth delay element 12, corresponding to the extreme value of K _g (τ _i-1 ) = K ^* _g availability coefficient, through the fifth key 19 is supplied to the fourth output of the device and to the first input of the second multiplier 23.

In the second multiplier 23, the operational availability coefficient is calculated in accordance with (8). The output signal of the multiplier 23 K _og (t) = K ^* _g · P (ξ) is transmitted to the fifth output of the device.

This completes the operation of the device.

The positive effect that can be obtained from the application of the proposed technical solution consists in obtaining the calculated values of the uptime and the required maintenance time of the product with the optimal frequency of maintenance, ensuring the maximum possible readiness of the product for its intended use. The calculated values of the output values allow us to justify the plan of application and technical operation of the product.

When developing the device diagram, the functional elements described in [5] were used.

Information sources

1. Vorobev G.N., Grishin V.D., Timofeev A.N. A.S. USSR No. 1617453, M. Cl. ⁵ G07C 3/08, 1990

2. Vorobev G.N., Grishin V.D., Domozhirov V.T., Timofeev A.N. A.S. USSR No. 1773199, M. Cl. ⁵ G07C 3/08, 1992

3. Vorobev G.N., Grishin V.D., Moskvin B.V. A.S. USSR No. 1425745, M. Cl. ⁴ G07C 3/08, 1989

4. Grishin V.D., Vorobev G.N., Myshinsky D.A. RF patent No. 2279712, IPC 7 G07C 3/08, G06F 17/00, 2006

5. Tetelbaum IM, Schneider Yu.R. 400 schemes for AVM. - M .: Energy, 1978

Claims (1)

A device for determining the optimal period of maintenance of the product, containing the first adder, the output of which is connected to the first input of the second adder, the second input of the first adder is the third input of the device, which receives the parameter value

and the first input of the first adder is connected to the output of the first multiplier, the second input of which is the second input of the device to which the value

Where

- the average time for preventive maintenance,

- the average time for emergency repairs,

- the average time of health monitoring, the first input of the first multiplier is connected to the output of the first key and to the first input of the integrator, the second input of which is connected to the second input of the second adder, with the information input of the second key and with the output of the time sensor directly, and through the fifth delay element connected in series and the eighth key - with the third output of the device, which receives the value of the optimal period of maintenance of the product τ ^* , the fourth output of the device on which the signal is generated l, corresponding to the extreme value of the availability factor K * _g , is connected with the first input of the second multiplier and with the output of the fifth key, the information input of which is connected to the output of the fourth delay element, and the permitting input of which, together with the enable inputs of the first, second, third, seventh, eighth and ninth key is connected to the second output of the comparator, which signal is generated in the case of _{plaster Gi} K <K _{plaster Gi-1,} where K and K _{plaster Gi plaster Gi-1} - current and previous values of the served product availability ratio, first you od comparator, which signal is generated if K _{plaster Gi} ≥K _{plaster Gi-1} is connected to the input time of the sensor, a first input directly, while the second input via a fourth delay element connected to the output of the first divider, the second input of which is connected to the output of the integrator, and the first input is connected directly to the output of the second adder, and through the second delay element, to the information input of the seventh key, the output of which is connected to the first input of the third multiplier and to the second input of the second division unit, the first input of which evyaty key is connected to a fourth input of the device, which receives the value of T _f, which characterizes the interval on which produce service, and directly - the first input of the subtractor, and an output connected to the second input of the third multiplier, whose output is connected to a second input of the subtractor, the output of which connected to the first input of the OR circuit, the second input of which is connected to the output of the second key, and the output is connected to the second input of the nonlinearity block, the first input of which is the first input of the device to which the s λ, which characterizes the intensity value of the product failures, and an output coupled to the data inputs of the first switch and the third switch, whose output is connected to a second input of the second multiplier, whose output is the fifth output device which receives a signal corresponding to the value of the operational readiness of the coefficient K _ar, characterized in that the first and third delay elements, the fourth and sixth keys are introduced into it, and the output of the first adder through the first delay element is connected to the information input of the pole the key, whose enable input is connected to the second output of the comparator, and the output is the first output of the device, which receives a signal corresponding to the value of the product maintenance time τ * _obs , the second output of the device, which receives a value corresponding to the average operating time of the product τ * _p is the output of the fourth switch, the enabling input connected to the second output of the comparator, and an information input via a third delay element connected to the output of integrator .