RU2736880C1 - Method for preventive unloading of independent electric power system - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention can be used in electrical engineering for protection of shipboard and other autonomous electric power systems (AEPS) with parallel-running generator units (GS) in case of failure of one or more of them. According to the method, with failure of one or more generator units (GS), a mode is determined, in which AEPS functions, which is characterized by the composition of working, as well as switched to nonoperational state, but continuing to operate GS, and selecting corresponding to that mode value of total allowable active load for disabling disable or inoperative GS (Ptot.all.dis.i), from number of total allowable active loads for disconnection of inoperative or inoperative GS (Ptot.all.dis.1, Ptot.all.dis.2 … Ptot.all.dis.i… Ptot.all.dis.m), calculated in advance for the whole number (m) of controlled modes of operation of AEPS, calculating the value of total active load of the entire AEPS at a given time (Ptot.i), comparing the calculated value Ptot.iwith the permissible value Ptot.per.dis.iand at Ptot.i> Ptot.per.dis.igenerating a signal for disconnection of a part of electric energy consumers until disabling the inoperative GS.EFFECT: faster disconnection of part of load until disconnection of inoperative GS and prevention of network overload.1 cl, 2 dwg

Description

The invention relates to the field of electrical engineering and can be used to protect autonomous electric power systems (NPP) from overload.

There is a known method of automatic unloading of parallel operating generating sets (Patent for invention No. 2623106, published in Bul. No. 18 of 06/22/2017), according to which the technical condition of each HU is continuously monitored by measuring a parameter characterizing its operating state and comparing the measured parameter with a critical value, and when the compared values coincide, a signal is generated to sum up the measured active loads of both HA, while if the total active load of a HA exceeds the permissible value of the load of one HA, then, until the emergency shutdown of an inoperative HA, a signal is generated to turn off preselected electricity consumers.

This method is well implemented for the case of parallel operation of two HA and cannot be used if the number of HA is more than two.

The closest to the proposed method is the method of automatic unloading of the electric power system (EES) with parallel operating generator sets (GA) under the patent RU 2653361 C1, 05/08/2018, which consists in the fact that in the event of failure of one or more GA, the active load of each GA is measured Pi), calculate the value of the total active load of the entire EPS (Psum.i), calculate the value of the total permissible active load of the EPS (Psum.add.off) for cases of disconnecting an inoperative or inoperative GA, compare the calculated value of Psum.i with the permissible value of Psum. additional off. and at Rsum.i> Rsum.add.def. generate a signal to disconnect the selected consumers of electrical energy until the disconnection of inoperative HA.

This method makes it possible to generate a signal to turn off some of the consumers until the inoperable HA is turned off and to avoid overloading the remaining operable units.

The disadvantage of this method is not sufficient performance in practical implementation, due to the need to perform computational operations to determine the value of the total permissible load of the EPS for cases of disconnecting an inoperative (inoperative) GA directly during the decision on the advisability of disconnecting some consumers.

The aim of the invention is to increase the speed of the method.

To achieve the specified technical result, the following set of essential features is used: when one or more generator sets (GA) fail, the mode is determined in which the NPP operates, characterized by the composition of the operating, as well as those that have passed into an inoperative state, but continue to operate, and the appropriate for this mode, the value of the total permissible active load for cases of disconnection of an inoperative or inoperative GA (Ptot.add.offi .off.2… Ptot.add.offi ... Ptot.add.off.m), calculated in advance for the entire number (m) of controlled modes of NPP operation, calculate the value of the total active load of the entire NPP at a given time (Psum.i ), compare the calculated value of Ptot.i with the permissible value of Ptot.add.dev.i and when Ptot.i> Ptot.to off i form a signal to turn off some of the consumers of electrical energy until the inoperable HA is turned off.

The essence of the invention lies in the fact that in the proposed method, as in the prototype, in case of failure of one or more HA, the total active load of the entire NPP is calculated for a given mode of operation at a given time (Psum.i), the power consumers are disconnected before the emergency shutdown of the inoperative unit and if the condition Ptot.i> Ptot.add.dep.i is met, however, in the method adopted for the prototype, the value of Ptot.add.dep.i is calculated directly during the decision on the expediency of signal generation on the disconnection of a group of electricity consumers, which somewhat delays and complicates the decision-making process, and in the proposed method, the value of Psum.add.dev.i is calculated for this mode in advance before the stage of making a decision on the advisability of generating a signal to disconnect part of the consumers. At the same time, the determination of the mode in which the NPP operates allows you to unambiguously select the corresponding value Ptot.add.dev.i from the set Ptot.add.dev. 1, Pt.add.dev. 2… Pt.add.dev.i ... additional deviation m, where 1, 2, ... i ... m are the controlled modes of the NPP operation, hereinafter characterized by the composition of the working, as well as those that have passed into an inoperative state, but continue to operate the HA (each i-th mode functioning corresponds to the pre-calculated value of Ptot.add.dev.i, which means that determining the mode of operation of the NPP, it is possible to identify and select the value of Ptot.add.dev.i).

Thus, the proposed invention makes it possible to solve the problem of controlling the disconnection of a part of consumers when at least one of the operating HA goes into an inoperative state in a different way than the prototype and other known technical solutions.

Since the determination of the operating mode of the NPP is a logical task, the solution of which by means of computer technology generally takes less time than the solution of the calculation problem, it can be recognized that the proposed approach has a higher performance than the method taken as a prototype.

Comparison of the proposed method and the prototype showed that the task - to increase the speed of the method - is solved as a result of a new set of features, which proves the compliance of the proposed invention with the "novelty" criterion of patentability.

In turn, the conducted information search in the field of power supply did not reveal solutions containing individual distinctive features of the claimed invention, which allows us to conclude that the method meets the criterion of "inventive step".

The essence of this method is illustrated by a drawing, where:

in FIG. 1 shows a functional diagram of a device that implements the proposed method, using the example of parallel operation of n GA with the number of controlled operating modes of the NPP equal to m.

The device (Fig. 1) contains, according to the number of GAs: 1.1, 1.2 ... 1.n - active load sensors, 2.1, 2.2 ... 2.n - blocks for monitoring the operation of the corresponding GA, 3.1, 3.2 ... 3.n - blocks for determining the technical state of the corresponding GA; and also 4 - addition block, 5 - block for determining the NPP operation mode; by the number of controlled NPP operation modes: 6.1, 6.2… 6.m - memory blocks, 7.1, 7.2… 7.m - controlled keys; and, in addition, 8 - comparison unit, 9 - logical element "OR" and 10 - block for switching off consumers; while the outputs of active load sensors 1.1, 1.2 ... 1.n are connected to the corresponding inputs of the addition unit 4, the output of which is connected to the first input of the comparison unit 8; the output of each of the blocks for monitoring the operation of the corresponding GA 2.1, 2.2 ... 2.n is connected to the corresponding of the first inputs of the unit for determining the mode of operation of the NPP 5, the output of each of the blocks for determining the technical state of the corresponding GA 3.1, 3.2 ... 3.n is connected to the corresponding of the second inputs unit for determining the mode of operation of the NPP 5, each of the first outputs of which is connected to the control input of the corresponding controlled key 7.1, 7.2 ... 7.m; the output of each of the memory blocks 6.1, 6.2 ... 6.m is connected to the information input of the corresponding controlled key 7.1, 7.2 ... 7.m, the output of each of which is connected to the second input of the comparison unit 8; the output of the comparison unit 8 is connected to the first input of the logical element "OR" 9, the second output of the block for determining the mode of operation of the NPP 5 is connected to the second input of the logical element "OR" 9, the output of which is connected to the input of the block for disconnecting consumers 10, the output of block 10 is the output of the device ...

Active load sensors GA 1.1, 1.2 ... 1.n are known functional blocks, at the outputs of each of which signals are generated proportional to the active load of the corresponding GA.

Blocks for monitoring the operation of the corresponding GA 2.1, 2.2 ... 2.n - known functional blocks, at the output of which a logical "1" signal is generated, if the corresponding GA is working and the signal is logical "0", if the corresponding GA is not working as part of the NPP at a given time ... As these blocks can be used a block of contacts of generator circuit breakers or shaft speed sensors of the corresponding engine.

Blocks for determining the technical state of the corresponding GA - 3.1, 3.2 ... 3.n - known functional blocks, at the output of which a logical "1" signal is generated, if at least one of the monitored parameters (temperature of cooling water or diesel lubricating oil, etc.) went out of tolerance and indicates an inoperative state of the GA and a logic "0" signal if all monitored parameters are normal. A circuit similar to the one that generates a generalizing alarm signal (APS) on the ship when the temperature of the cooling water or diesel engine lubricating oil is exceeded can be used as a technical condition monitoring unit.

Adding unit 4 is a well-known functional unit, at the output of which a signal is generated proportional to the sum of signals at its inputs, can be performed on the basis of operational amplifiers.

The unit for determining the operating mode of the NPP 5 is a new unit that has n first and n second inputs, where n is the number of GAs included in the NPP, and m first outputs, where m is the number of controlled modes of NPP operation and one second (emergency) output. In the case of transition of one or several operating HA to an inoperative state, unit 5 evaluates logical signals arriving at its first and second inputs and at one of its m first outputs, which corresponds to the AEES operation mode at a given time, a logical “1” signal appears. All other first outputs have a logic “0” signal. If all working HA fails at once, then the logical "1" signal will appear at the second output of block 5. FIG. 2 shows one of the possible functional diagrams of the unit for determining the mode of operation of AEES 5 for the case of an AEES, which has three GA (n = 3). The unit for determining the operating mode of the NPP 5, the functional diagram of which is shown in Fig. 2, contains: 11.1, 11.2 ... 11.30 - logical elements "AND", 12.1, 12.2 ... 12.6 - logical elements "NOT", 13 - logical gate "OR - NOT" and 14 - logical gate "OR", while the first input logical element "AND" 11.1, which is the first of the first inputs of block 5, is connected to the input of the logical element "NOT" 12.1, the first inputs of the logical elements "AND" 11.4, 11.5 and 11.7; the first input of the logical element "AND" 11.2, which is the second of the first inputs of block 5, is connected to the input of the logical element "NOT" 12.2, the second input of the logical element "AND" 11.4 and the first input of the logical element "AND" 11.6, the second input of the logical element " I "11.7; the first input of the logical element "AND" 11.3, which is the third of the first inputs of block 5, is connected to the input of the logical element "NOT" 12.3, the second inputs of the logical elements "AND" 11.5 and 11.6 and the third input of the logical element "AND" 11.7, the output of which is connected with the first inputs of the logic elements "AND" 11.18, 11.25, 11.26, 11.27, 11.28, 11.29, 11.30; the output of the logical element "NOT" 12.1 is connected to the second inputs of the logical elements "AND" 11.2, 11.3 and the third input of the logical element "AND" 11.6; the output of the logical element "NOT" 12.2 is connected to the second input of the logical element "AND" 11.1 and the third inputs of the logical elements "AND" 11.3 and 11.5; the output of the logical element "NOT" 12.3 is connected to the third inputs of the logical elements "AND" 11.1, 11.2 and 11.4; the output of the logical element "AND" 11.1 is connected to the first output of the block 5 and the first input of the logical element "AND" 11.8, the output of which is connected to the first input of the second logical element "OR" 14; the output of the logical element "AND" 11.2 is connected to the second output of the block 5 and the first input of the logical element "AND" 11.9, the output of which is connected to the second input of the second logical element "OR" 14; the output of the logical element "AND" 11.3 is connected to the third output of the block 5 and the first input of the logical element "AND" 11.10, the output of which is connected to the third input of the second logical element "OR" 14; the output of the logical element "AND" 11.4 is connected to the first inputs of the logical elements "AND" 11.11, 11.15, 11.19 and 11.20; the output of the logical element "AND" 11.5 is connected to the first inputs of the logical elements "AND" 11.12, 11.16, 11.21 and 11.22; the output of the logical element "AND" 11.6 is connected to the first inputs of the logical elements "AND" 11.13, 11.17, 11.23 and 11.24; the input of the logical element "NOT" 12.4, which is the first of the second inputs of block 5, is connected to the first input of the logical element "AND" 11.14, with the second inputs of the logical elements "AND" 11.8, 11.11, 11.12, 11.25, 11.28 and 11.29, with the third inputs logical elements "AND" 11.19, 11.21, the first input of the logical element "OR - NOT" 13; the input of the logical element "NOT" 12.5, which is the second of the second inputs of block 5, is connected to the second inputs of the logical elements "AND" 11.9, 11.13, 11.14, 11.26, 11.30, with the third inputs of the logical elements "AND" 11.11, 11.20, 11.23 and 11.28 , the second input of the logical element "OR - NOT" 13; the input of the logical element "NOT" 12.6, which is the third of the second inputs of block 5, is connected to the second inputs of the logical elements "AND" 11.10 and 11.27, to the third inputs of the logical elements "AND" 11.12, 11.13, 11.14, 11.22, 11.24, 11.29 and 11.30, with the third input of the logical element "OR - NOT" 13, the output of which is connected to the second inputs of the logical elements "AND" 11.15, 11.16, 11.17 and 11.18; the output of the logical element "NOT" 12.4 is connected to the second inputs of the logical elements "AND" 11.20, 11.22, with the third inputs of the logical elements "AND" 11.26, 11.27 and the fourth input of the logical element "AND" 11.30; the output of the logical element "NOT" 12.5 is connected to the second inputs of the logical elements "AND" 11.19, 11.24, with the third input of the logical element "AND" 11.25, with the fourth inputs of the logical elements "AND" 11.27 and 11.29; the output of the logical element "NOT" 12.6 is connected to the second inputs of the logical elements "AND" 11.21, 11.23, with the fourth inputs of the logical elements "AND" 11.25, 11.26 and 11.28; the output of the logical element "AND" 11.11 is connected to the fourth input of the logical element "OR" 14, the output of the logical element "AND" 11.12 is connected to the fifth input of the logical element "OR" 14, the output of the logical element "AND" 11.13 is connected to the sixth input of the logical element " OR 14, the output of the AND gate 11.14 is connected to the seventh input of the OR gate 14, the output of which is the second output of block 5; the output of the logical element "AND" 11.15 is the fourth of the first outputs of block 5, the output of the logical element "AND" 11.16 is the fifth of the first outputs of block 5, the output of the logical element "AND" 11.17 is the sixth of the first outputs of block 5, the output of the logical element "AND "11.18 is the seventh of the first outputs of block 5, the output of the AND gate 11.19 is the eighth of the first outputs of block 5, the output of the AND gate 11.20 is the ninth of the first outputs of block 5, the output of the AND gate 11.21 is the tenth of the first outputs of block 5, the output of the logical element "AND" 11.22 is the eleventh of the first outputs of block 5, the output of the logical element "AND" 11.23 is the twelfth of the first outputs of block 5, the output of the logical element "AND" 11.24 is the thirteenth of the first outputs of block 5, the output of the logical element "AND" 11.25 is the fourteenth of the first outputs of block 5, the output of the logical element "AND" 11.26 is the fifteenth of the first outputs of block 5, the output the logical element "AND" 11.27 is the sixteenth of the first outputs of block 5, the output of the logical element "AND" 11.28 is the seventeenth of the first outputs of block 5, the output of the logical element "AND" 11.29 is the eighteenth of the first outputs of block 5, the output of the logical element "AND" 11.30 is the nineteenth of the first outputs of block 5.

The unit for determining the operating mode of the NPP 5, the functional diagram of which is shown in Fig. 2 works as follows. Each (first, second and third) of the first inputs of block 5 receives signals of logical "1", if, respectively, the first, second and third HA are working. Each (first, second and third) of the second inputs of block 5 receives signals of logical "1", if, respectively, the first, second and third GA passed into an inoperative state. If the logical "1" signal arrives only at the first of the first inputs of block 5, and at all other inputs - the logical "0" signal, then the first input of the logical element "AND" 11.1 receives the logical "1" signal from the first of the first inputs of the block 5. The logical "0" signal from the second of the first inputs of block 5 is fed to the input of the logical element "NOT" 12.2 and a logical "1" signal is generated at its output, which is fed to the second input of the logical element "AND" 11.1. The logical "0" signal from the third of the first inputs of block 5 is fed to the input of the logical element "NOT" 12.3 and a logical "1" signal is generated at its output, which is fed to the third input of the logical element "AND" 11.1. Since all three inputs of the logical element "AND" 11.1 received signals of the logical "1", then a logical "1" signal appears at its output and the first of the first outputs of block 5, informing that the AEES operates in the mode in which it operates GA1 and GA2 and GA3 do not work. This signal also goes to the first input of the logical element "AND" 11.8. If, in this case, the transition of GA1 to an inoperative state occurs, then a logical "1" signal is sent to the first of the second inputs of block 5, which is transmitted to the second input of the logical element "AND" 11.8 and a logical signal "1" is generated at its output, which is fed to the first input of the logical element "OR" 14. At the output of the logical element "OR" 14 and the second output of block 5, a logical "1" signal appears, informing that all the GAs working at the moment are out of order.

The circuit works in a similar way if only a logical “1” signal is received at the second of the first inputs of block 5. In this case, the logical "1" signal is fed to the first input of the logical element "AND" 11.2 directly from the second of the first inputs of block 5. The logical "0" signal from the first of the first inputs of block 5 is fed to the input of the logical element "NOT" 12.1, to its output appears a signal of logical "1" and comes to the second input of the logical element "AND" 11.2. The signal of logical "0" from the third of the first inputs of block 5 is fed to the input of the logical element "NOT" 12.3, at its output a signal of logical "1" appears and comes to the third input of the logical element "AND" 11.2. Since all three inputs of the logical element "AND" 11.2 received signals of logical "1", then at its output and the second of the first outputs of block 5 there is also a signal of logical "1", informing that the AEES operates in a mode in which GA2 works, but GA1 and GA3 do not work. This signal is also fed to the first input of the logical element "AND" 11.9. If, in this case, the transition of GA2 to an inoperative state occurs, then a logical "1" signal is sent to the first of the second inputs of block 5, which is transmitted to the second input of the logical element "AND" 11.9 and a logical signal "1" is generated at its output, which is fed to the second input of the logical element "OR" 14. At the output of the logical element "OR" and the second output of block 5, a signal of logical "1" appears, informing that all the GAs working at the moment are out of order.

If only the third of the first inputs of block 5 received a logical "1" signal, then in this case the logical "1" signal arrives at the first input of the logical element "AND" 11.3 directly from the third of the first inputs of block 5. The logical "0" signal with the first of the first inputs of block 5 is fed to the input of the logical element "NOT" 12.1, at its output a signal of the logical "1" appears and comes to the second input of the logical element "AND" 11.3. The logical "0" signal from the second of the first inputs of block 5 is fed to the input of the logical element "NOT" 12.2, at its output a logical "1" signal appears and comes to the third input of the logical element "AND" 11.3. Since all three inputs of the logical element "AND" 11.3 received signals of a logical "1", then at its output and the third of the first outputs of block 5 there is also a signal of a logical "1", informing that the AEES operates in a mode in which GA3 works, but GA1 and GA2 do not work. This signal is also fed to the first input of the logical element "AND" 11.10. If, in this case, the transition of GA3 to an inoperative state occurs, then a logical "1" signal is received at the third of the second inputs of block 5, which is transmitted to the second input of the logical element "AND" 11.10 and a logical "1" signal is generated at its output, which is fed to the third input of the logical element "OR" 14. At the output of the logical element "OR" and the second output of block 5, a signal of logical "1" appears, informing that all the GAs working at the moment are out of order.

If the signals of logical "1" arrive only at the first and second of the first inputs of block 5, then they come to the first and second inputs of the logical element "AND" 11.4, respectively. The logical "0" signal from the third input of block 5 is fed to the input of the logical element "NOT" 12.3, a logical "1" signal appears at its input and comes to the third input of the logical element "AND" 11.4. Since all three inputs of the logical element "AND" 11.4 received signals of a logical "1", then a logical "1" signal is generated at its output, informing that the AEES operates in a mode in which HA1 and HA2 operate, and HA3 - no. This signal arrives at the first inputs of the logic elements "AND" 11.11, 11.15, 11.19 and 11.20. Since all three of the second inputs of block 5 receive signals of logical "0", they come to the corresponding three inputs of the logical element "OR - NOT" 13, at the output of which a logical "1" signal is generated, informing that all GA workable. This signal is fed to the second inputs of the logic elements "AND" 11.15, 11.16, 11.17, 11.18. Since both inputs of the logical element "AND" 11.15 received the signals of the logical "1", then at its output and the fourth of the first outputs of block 5 there is a signal of the logical "1", informing that the AEES operates in the mode in which GA1 operates and GA2, both are functional, but GA3 is not working. If, in this case, GA1 goes into an inoperative state, then a logical "1" signal will be sent to the first of the second inputs of block 5. This signal will go to the second inputs of the logic elements "AND" 11.8, 11.11, 11.12, 11.25, 11.28, 11.29, the first input of the logic element "AND" 11.14, the third inputs of the logic elements "AND" 11.19 and 11.21. Since the second of the second inputs of block 5 receives a logical "0" signal, it is fed to the input of the logical element "NOT" 12.5, at the output of which a logical "1" signal appears and goes to the second input of the logical element "AND" 11.19. Since all three inputs of the logical element "AND" 11.19 received signals of the logical "1", then a logical "1" signal appears at its output and at the eighth output of block 5, informing that the NPP is operating in the mode in which GA1 operates and GA2, and GA3 - not, and at the same time GA1 went into an inoperative state. In this case, the signal of logical "1" from the first of the second inputs of block 5 will go to the first input of the logical element "OR-NOT" 13, a logical signal "0" will appear at its output, and will go to the second input of the logical element "AND" 11.15 at its output , which means that a logical "0" signal will appear at the fourth output of block 5. If in this case not GA1 but GA2 goes into an inoperative state, then a logical "1" signal will be sent to the second of the second inputs of block 5. This signal will arrive at the second inputs of the logic elements "AND" 11.9, 11.13, 11.14, 11.26, 11.30, the third inputs of the logic elements "AND" 11.11, 11.20, 11.23 and 11.28. Since the first of the second inputs of block 5 receives the signal of the logical "0 ", Then it is fed to the input of the logical element" NOT "12.4, at the output of which a logical" 1 "signal appears and goes to the second input of the logical element" AND "11.20. Since all three inputs of the logical element "AND" 11.20 received the signals of the logical "1", then a logical "1" signal appears at its output and at the ninth output of block 5, informing that the AEES operates in the mode in which GA1 operates and GA2, and GA3 - no, and at the same time GA2 went into an inoperative state. In this case, the signal of logical "1" from the second of the second inputs of block 5 will go to the second input of the logical element "OR-NOT" 13, at its output a signal of logical "0" will appear, will go to the second input of the logical element "AND" 11.15 at its output , which means that a logical "0" signal will appear at the fourth output of block 5. If at the same time GA1 and GA2 both go into an inoperative state, then the first and second of the second inputs of BLOCK 5, and from there to the second and third inputs of the logical element "AND" 11.11, respectively, will receive signals of the logical "1". Since the first input of the logical element "AND" 11.11 receives a signal of the logical "1" from the output of the logical element "AND" 11.4, then the output 11.11 also generates a signal of the logical "1" and enters the fourth input of the logical element "OR" 14, to the output of which and the second output of block 5 a logical "1" signal appears, informing that the NPP is operating in a mode in which all operating HA are inoperative.

If the signals of logical "1" arrive only at the first and third of the first inputs of block 5, then they arrive at the first and second inputs of the logical element "AND" 11.5, respectively. The logical "0" signal from the second input of block 5 is fed to the input of the logical element "NOT" 12.2, a logical "1" signal appears at its input and comes to the third input of the logical element "AND" 11.5. Since all three inputs of the logical element "AND" 11.5 received signals of a logical "1", a logical "1" signal is generated at its output, informing that the AEES operates in a mode in which HA1 and HA3 operate, and HA2 - no. This signal arrives at the first inputs of the logical elements "AND" 11.12, 11.16, 11.21 and 11.22. Since all three of the second inputs of block 5 receive signals of logical "0", they come to the corresponding three inputs of the logical element "OR - NOT" 13, at the output of which a logical "1" signal is generated, informing that all GA workable. This signal arrives at the second inputs of the logic elements "AND" 11.15, 11.16, 11.17, 11.18. Since both inputs of the logical element "AND" 11.16 received the signals of the logical "1", then at its output and the fifth of the first outputs of block 5 there is a signal of the logical "1", informing that the AEES operates in the mode in which GA1 operates and GA3, both are functional, but GA2 is not working. If in this case the GA1 goes into an inoperative state, then a logical "1" signal will be sent to the first of the second inputs of block 5. This signal will go to the second inputs of the logic elements "AND" 11.8, 11.11, 11.12, 11.25, 11.28, 11.29, the first input of the logic element "AND" 11.14, the third inputs of the logic elements "AND" 11.19 and 11.21. Since the third of the second inputs of block 5 receives a logical "0" signal, it is fed to the input of the logical element "NOT" 12.6, at the output of which a logical "1" signal appears and goes to the second input of the logical element "AND" 11.21. Since all three inputs of the logical element "AND" 11.21 received signals of the logical "1", then a logical "1" signal appears at its output and at the tenth output of block 5, informing that the AEES operates in the mode in which GA1 operates and GA3, and GA2 - no, and at the same time GA1 went into an inoperative state. In this case, the signal of logical "1" from the first of the second inputs of block 5 will go to the first input of the logical element "OR-NOT" 13, a logical signal "0" will appear at its output, it will go to the second input of the logical element "AND" 11.16 at its output , which means that a logical "0" signal will appear at the fifth output of block 5. If in this case not GA1 but GA3 goes into an inoperative state, then a logical "1" signal will be sent to the third of the second inputs of block 5. This signal will go to the second inputs of the logic elements "AND" 11.10, 11.27, the third inputs of the logic elements "AND" 11.12, 11.13, 11.14, 11.22, 11.24, 11.29 and 11.30. Since the first of the second inputs of block 5 receives a logical "0" signal, it is fed to the input of the logical element "NOT" 12.4, at the output of which a logical "1" signal appears and goes to the second input of the logical element "AND" 11.22. Since all three inputs of the logical element "AND" 11.22 received signals of a logical "1", then a logical "1" signal appears at its output and at the eleventh output of block 5, informing that the AEES operates in a mode in which GA1 operates and GA3, and GA2 - not, and at the same time GA3 went into an inoperative state. In this case, the signal of logical "1" from the second of the third of the second inputs of block 5 will go to the second input of the logical element "OR-NOT" 13, at its output a signal of logical "0" will appear, will go to the second input of the logical element "AND" 11.16 to its output, and hence at the fifth output of block 5, a logical "0" signal will appear. If at the same time GA1 and GA3 both go into an inoperative state, then the first and third of the second inputs of block 5, and from there to the second and third inputs of the logical element "AND" 11.12, respectively, will receive the signals of the logical "1". Since the first input of the logical element "AND" 11.12 receives a signal of the logical "1" from the output of the logical element "AND" 11.5, then at the output 11.12 a signal of the logical "1" is also generated and goes to the fifth input of the logical element "OR" 14, to the output of which and the second output of block 5, a logical “1” signal appears, informing that the NPP is operating in a mode in which all operating HA are inoperative.

If the signals of logical "1" arrive only at the second and third of the first inputs of block 5, then they come to the first and second inputs of the logical element "AND" 11.6, respectively. The logical "0" signal from the first of the first inputs of block 5 is fed to the input of the logical element "NOT" 12.1, a logical "1" signal appears at its input and arrives at the third input of the logical element "AND" 11.6. Since all three inputs of the logical element "AND" 11.6 received signals of a logical "1", then a logical "1" signal is generated at its output, informing that the AEES operates in a mode in which HA2 and HA3 operate, and HA1 - no. This signal is fed to the first inputs of the logic elements "AND" 11.13, 11.17, 11.23 and 11.24. Since all three of the second inputs of block 5 receive signals of logical "0", they come to the corresponding three inputs of the logical element "OR - NOT" 13, at the output of which a logical "1" signal is generated, informing that all GA workable. This signal is fed to the second inputs of the logic elements "AND" 11.15, 11.16, 11.17, 11.18. Since both inputs of the logical element "AND" 11.17 received the signals of the logical "1", then at its output and the sixth of the first outputs of block 5 there is a signal of the logical "1", informing that the AEES operates in the mode in which GA2 operates and GA3, both are functional, but GA1 is not working. If, in this case, GA2 goes into an inoperative state, then a logical "1" signal will be sent to the second of the second inputs of block 5. This signal will go to the second inputs of the logic elements "AND" 11.9, 11.13, 11.14, 11.26, 11.30, the third inputs of the logic elements "AND" 11.11, 11.20, 11.23 and 11.28. Since the third of the second inputs of block 5 receives a logical "0" signal, it is fed to the input of the logical element "NOT" 12.6, at the output of which a logical "1" signal appears and goes to the second input of the logical element "AND" 11.23. Since all three inputs of the logical element "AND" 11.23 received signals of the logical "1", then at its output and at the twelfth output of block 5, a logical signal "1" appears, informing that the AEES operates in the mode in which GA2 and GA3, and GA1 not, and at the same time GA2 passed into an inoperative state. In this case, the signal of logical "1" from the second of the second inputs of block 5 will go to the second input of the logical element "OR-NOT" 13, at its output a signal of logical "0" will appear, which will go to the second input of the logical element "AND" 11.17 to its output, and hence at the sixth output of block 5, a logical "0" signal will appear. If, in this case, not GA2, but GA3 goes into an inoperative state, then a logical "1" signal will be sent to the third of the second inputs of block 5. This signal will go to the second inputs of the logic elements "AND" 11.10, 11.27, the third inputs of the logic elements "AND" 11.12, 11.13, 11.14, 11.22, 11.24, 11.29 and 11.30. Since the second of the second inputs of block 5 receives a logical "0" signal, it is fed to the input of the logical element "NOT" 12.5, at the output of which a logical "1" signal appears and goes to the second input of the logical element "AND" 11.24. Since all three inputs of the logical element "AND" 11.24 received signals of the logical "1", then a logical "1" signal appears at its output and at the thirteenth output of block 5, informing that the AEES operates in a mode in which GA2 operates and GA3, and GA1 - no, and at the same time GA3 went into an inoperative state. In this case, the signal of logical "1" from the third of the second inputs of block 5 will go to the third input of the logical element "OR-NOT" 13, at its output a signal of logical "0" will appear, will go to the second input of the logical element "AND" 11.17 at its output , which means that a logical "0" signal will appear at the sixth output of block 5. If in this case GA21 and GA3 both go into an inoperative state, then the signals of the logical “1” will be sent to the second and third of the second inputs of block 5, and from there to the second and third inputs of the logical element "AND" 11.13. Since the first input of the logical element "AND" 11.13 receives a signal of the logical "1" from the output of the logical element "AND" 11.6, then the output 11.13 also generates a signal of the logical "1" and goes to the sixth input of the logical element "OR" 14, to the output of which and the second output of block 5, a logical "1" signal appears, informing that the NPP is operating in a mode in which all operating HA are inoperative.

If the signals of logical "1" arrive at the first, second and third of the first inputs of block 5, then they arrive at the first, second and third inputs of the logical element "AND" 11.7, respectively. Since all three inputs of the logical element "AND" 11.7 received signals of a logical "1", then a logical "1" signal is generated at its output, informing that the AEES operates in a mode in which HA1, HA2 and HA3 operate. This signal arrives at the first inputs of the logical elements "AND" 11.18, 11.25, 11.26, 11.27, 11.28, 11.29 and 11.30. Since all three of the second inputs of block 5 receive signals of logical "0", they come to the corresponding three inputs of the logical element "OR - NOT" 13, at the output of which a logical "1" signal is generated, informing that all GA workable. This signal is fed to the second inputs of the logic elements "AND" 11.15, 11.16, 11.17, 11.18. Since both inputs of the logical element "AND" 11.18 received signals of a logical "1", then at its output and the seventh of the first outputs of block 5 there is a signal of a logical "1", informing that the AEES operates in a mode in which both work and all three units are operational: GA1, GA2 and GA3. If, in this case, GA1 goes into an inoperative state, then a logical "1" signal will be sent to the first of the second inputs of block 5. This signal will go to the second inputs of the logic elements "AND" 11.8, 11.11, 11.12, 11.25, 11.28, 11.29, the first input of the logic element "AND" 11.14, the third inputs of the logic elements "AND" 11.19 and 11.21. Since the second of the second inputs of block 5 receives a logical "0" signal, it is fed to the input of the logical element "NOT" 12.5, at the output of which a logical "1" signal appears and goes to the third input of the logical element "AND" 11.25. Since the third of the second inputs of block 5 receives a logical "0" signal, it is fed to the input of the logical element "NOT" 12.6, at the output of which a logical "1" signal appears and goes to the fourth input of the logical element "AND" 11.25. how all four inputs of the logical element "AND" 11.25 received signals of the logical "1" (the first input of the element "AND" 11.25 receives a signal in the form of a logical "1" that all three GAs are working from the output of the logical element "AND" 11.7 ), then a logical "1" signal appears at its output and at the fourteenth output of unit 5, informing that the NPP is operating in a mode in which GA1, GA2 and GA3 operate and at the same time GA1 has passed into an inoperative state. In this case, the signal of logical "1" from the first of the second inputs of block 5 will go to the first input of the logical element "OR-NOT" 13, a logical signal "0" will appear at its output, and will go to the second input of the logical element "AND" 11.18 at its output , which means that a logical "0" signal will appear at the seventh output of block 5. If in this case not GA1 but GA2 goes into an inoperative state, then a logical "1" signal will be sent to the second of the second inputs of block 5. This signal will go to the second inputs of the logic elements "AND" 11.9, 11.13, 11.14, 11.26, 11.30, the third inputs of the logic elements "AND" 11.11, 11.20, 11.23 and 11.28. Since the first of the second inputs of block 5 receives a logical "0" signal, it is fed to the input of the logical element "NOT" 12.4, at the output of which a logical "1" signal appears and goes to the third input of the logical element "AND" 11.26. Since the third of the second inputs of block 5 receives a logical "0" signal, it is fed to the input of the logical element "NOT" 12.6, at the output of which a logical "1" signal appears and is fed to the fourth input of the logical element "AND" 11.26. Since all four inputs of the logical element "AND" 11.26 received signals of a logical "1", then at its output and at the fifteenth of the first outputs of block 5, a signal of logical "1" appears, informing that the AEES operates in a mode in which GA1, GA2 and GA3 work, and GA2 went into an inoperative state. In this case, the signal of logical "1" from the second of the second inputs of block 5 will go to the second input of the logical element "OR-NOT" 13, a logical signal "0" will appear at its output, and will go to the second input of the logical element "AND" 11.18 at its output , which means that a logical "0" signal will appear at the seventh output of block 5. If, in this case, only GA3 goes into an inoperative state, then a logical “1” signal will be sent to the third of the second inputs, and from there to the second input of the logical element "AND" 11.27. Since the first of the second inputs of block 5 receives a logical "0" signal, it is fed to the input of the logical element "NOT" 12.4, at the output of which a logical "1" signal appears and goes to the third input of the logical element "AND" 11.27. Since the third of the second inputs of block 5 receives a logical "0" signal, it is fed to the input of the logical element "NOT" 12.6, at the output of which a logical "1" signal appears and goes to the fourth input of the logical element "AND" 11.27. Since all four inputs of the logical element "AND" 11.27 received signals of the logical "1", then at its output and at the sixteenth of the first outputs of block 5, a signal of logical "1" appears, informing that the AEES operates in a mode in which GA1, GA2 and GA3 work, and GA3 went into an inoperative state.

If at the same time GA1 and GA2 go into an inoperative state, then a logical "1" signal will be sent to the first of the second inputs of block 5. This signal will go to the second inputs of the logic elements "AND" 11.8, 11.11, 11.12, 11.25, 11.28, 11.29, the first input of the logic element "AND" 11.14, the third inputs of the logic elements "AND" 11.19 and 11.21. The second of the second inputs of block 5 will also receive a logical "1" signal. This signal will go to the second inputs of the logic elements "AND" 11.9, 11.13, 11.14, 11.26, 11.30, the third inputs of the logic elements "AND" 11.11, 11.20, 11.23 and 11.28. On the third of the second inputs of block 5, and hence on the input of the logical element "NOT" 12.6, a signal of logical "0" is received. At the output of the logical element "NOT" 12.6, a logical signal "1" is generated and fed to the fourth input of the logical element "AND" 11.28. Since at all four inputs of the logical element "AND" 11.28 there is a signal of a logical "1", then at its output, and therefore at the seventeenth output of block 5, a signal of a logical "1" appears informing that the AEES is operating in the mode, at which GA1, GA2 and GA3 work, and GA1 and GA2 went into an inoperative state.

If in this case GA1 and GA3 go into an inoperative state, then a logical "1" signal will be sent to the first of the second inputs of block 5. This signal will go to the second inputs of the logic elements "AND" 11.8, 11.11, 11.12, 11.25, 11.28, 11.29, the first input of the logic element "AND" 11.14, the third inputs of the logic elements "AND" 11.19 and 11.21. The third of the second inputs of block 5 will also receive a logical "1" signal. This signal will go to the second inputs of the logic elements "AND" 11.10, 11.27, the third inputs of the logic elements "AND" 11.12, 11.13, 11.14, 11.22, 11.24, 11.29 and 11.30. Since the second of the second inputs of block 5 receives a logical "0" signal, it is fed to the input of the logical element "NOT" 12.5, at the output of which a logical "1" signal appears and goes to the fourth input of the logical element "AND" 11.29. Since at all four inputs of the logical element "AND" 11.29 there is a logical "1" signal, then at its output, and therefore at the eighteenth output of block 5, a logical "1" signal appears informing that the AEES is operating in the mode, at which GA1, GA2 and GA3 work, and GA1 and GA3 are inoperative.

If in this case GA2 and GA3 go into an inoperative state, then a logical "1" signal will be sent to the second of the second inputs of block 5. This signal will go to the second inputs of the logic elements "AND" 11.9, 11.13, 11.14, 11.26, 11.30, the third inputs of the logic elements "AND" 11.11, 11.20, 11.23 and 11.28. The third of the second inputs of block 5 will also receive a logical "1" signal. This signal will go to the second inputs of the logic elements "AND" 11.10, 11.27, the third inputs of the logic elements "AND" 11.12, 11.13, 11.14, 11.22, 11.24, 11.29 and 11.30. Since the first of the second inputs of block 5 receives a logical "0" signal, it is fed to the input of the logical element "NOT" 12.4, at the output of which a logical "1" signal appears and goes to the fourth input of the logical element "AND" 11.30. Since at all four inputs of the logical element "AND" at 11.30 there is a signal of a logical "1", then at its output, and therefore at the nineteenth output of block 5, a signal of a logical "1" appears informing that the NPP is operating in the mode, in which GA1, GA2 and GA3 work and GA2 and GA3 are inoperative.

If all three GAs are working and have passed into an inoperative state, then all three of the second inputs of block 5 will receive signals of the logical "1", which will go to the first, second and third inputs of the logical element "AND" 11.14, respectively. Since all three inputs of the logical element "AND" 11.14 receive the signals of the logical "1", then at its output a signal of the logical "1" is also generated and fed to the seventh input of the logical element "OR" 14. At the same time, the output of the logical element "OR "14 and the second output of block 5, a logical" 1 "signal appears, informing that all currently operating GAs are inoperative.

Thus, in the case of the transition of one or several operating HA to an inoperative state, the unit for determining the mode of operation of the AEES 5 evaluates the logical signals arriving at its first and second inputs and at one of its first m outputs, which corresponds to the mode of functioning of the AEES at a given time, a logical "1" signal appears. All other first outputs have a logic “0” signal. If all working HA fails at once, then the logical "1" signal will appear at the second output of block 5.

Memory blocks 6.1, 6.2 ... 6.m are known functional blocks that store signals at their outputs in the form of a voltage proportional to the value of the total permissible active load of the NPP for cases of disconnecting an inoperative or inoperative HA, corresponding to each mode of operation of the NPP (Rsum.add.off. 1, Рsum.dop.opp. 2 ... Рsum.add.opp. M), where 1, 2… m are the numbers of the NPP operation modes.

Controlled keys 7.1, 7.2 ... 7.m are known functional blocks that generate signals at their outputs that are equal to signals at their information inputs in the event of a logical "1" signal arriving at their control inputs. These blocks are similar to those used in the device described in the prototype.

Comparison unit 8 is a well-known functional block that generates a logical "1" signal at its output if the signal received at its first input exceeds the signal received at its second input.

Logic element "OR" 9 is a well-known functional block, at the output of which a logical "1" signal is generated, if at least one of its inputs received a logical "1" signal.

Block for disconnecting part of consumers 10-well-known functional block that disconnects part of consumers when a logical "1" signal arrives at its input. As unit 10, an electromagnetic relay with an open contact can be used, connected in series to the circuit of the minimum release of the circuit breaker, with the help of which the disconnected consumers of electricity are connected to the buses of the main switchboard, and the coil is connected at one end to the zero bus, and the other to the input of the unit ...

Logic elements "AND" 11.1, 11.2 ... 11.30 (Fig. 2) are known functional blocks, at the outputs of each of which a logical "1" signal is generated only when a logical "1" signal is received at all its inputs.

Logic elements "NOT" 12.1, 12.2 ... 12.6 (Fig. 2) are known functional blocks that generate logic zero signals at their outputs when a logic "1" signal arrives at their inputs and generate logic "0" signals at their outputs, if their inputs are logical "1".

Logic element "OR-NOT" 13 (Fig. 2) is a well-known functional block, at the output of which a logical "0" signal is generated, if at least one of its inputs received a logical "1" signal.

A device that implements a method for preventive unloading of an autonomous electric power system, a functional diagram of which is shown in Fig. 1, operates as follows. The signals proportional to the current active load of the operating HA from the outputs of the active load sensors 1.1, 1.2 ... 1.n are fed to the corresponding inputs of the addition unit 4, at the output of which a signal is generated proportional to the active load of the NPP in this mode of operation Psum.i and goes to the first input of the comparison unit 8. Logical signals about the presence of the HA in the working or off state in the form of logical "1" and "0" are received from the outputs of the blocks for monitoring the operation of the HA 2.1, 2.2 ... 2.n to the corresponding from the first inputs of the block for determining the mode of operation of the AEES 5 . Logical signals about the presence of the GA in an inoperative or operable state in the form of logical "1" and "0" are received from the outputs of the blocks for determining the technical state of the GA 3.1, 3.2 ... 3.n to the corresponding from the second inputs of the block for determining the mode of operation of the NPP 5, on i -th of the first outputs of which a logical "1" signal is generated, informing that the NPP is in the i-th mode of operation. and not all working GAs are inoperable. The logical “1” signal from the i-th of the first outputs of block 5 is fed to the control input of the corresponding controlled key 7.i, the information input of which receives a signal proportional to the value of the total permissible active load of the NPP for cases of disconnection of an inoperative or inoperative GA corresponding to i- to the mode of operation of the NPP (Rsum.add.offi) from the output of the corresponding i-th memory block 6i. Controlled switch 7.i opens and at its output appears a signal proportional to Ptot.add.offi. I, which is fed to the second input of the comparison unit 8. Comparison unit 8 compares the signals arriving at the first and second inputs and, if the signal at the first input is greater than the signal arriving at its second input (the condition Psum.i> Psum.dop.opp.i) is satisfied, then a logical "1" signal is generated at the output of block 8. The logical "1" signal from the output of block 8 is fed to the first input of the logical element "OR" 9, at the output of which a logical "1" signal appears and goes to the input of the block for disconnecting part of consumers 10. Block 10 turns off some consumers, unloading the NPP. In the case when all the currently operating GAs have passed into an inoperative state, then at the second output of the unit for determining the operating mode of the AEES 5, a logical “1” signal will appear, which will go to the second input of the “OR” logic element 9. At the output of the “OR” logic element "9, a logical" 1 "signal will appear and will be fed to the input of the block for disconnecting a part of consumers 10, which will disconnect some of the consumers, unloading the NPP.

The logical "1" signal at the second output of the unit for determining the operating mode of the NPP 5 characterizes the pre-emergency mode of the system and can be used in the devices for emergency warning and preventive start-up of the emergency diesel generator, developed, for example, in accordance with the method of protecting the ship's electric power system under the patent RF No. 2681940 C1 dated 03/14/2019

An example of the implementation of the method.

As an example of applying the method, consider the operation of a nuclear power plant of a ship with three generator units: GA1 with a rated power of 200 kW (P1 = 200 kW), GA2 with a rated power of 160 kW (P2 = 160 kW) and GA3 with a rated power of 80 kW (P3 = 80 kW). Let us assume that all HA are new and capable of accepting the load corresponding to their rated power. In accordance with the proposed method, we will consider 19 controlled operating modes of the NPP (m = 19) and determine in advance Psum.add.dev.i for each operating mode. These values will be stored in the corresponding memory blocks 6.1, 6.2 ... 6.19 of the device, the functional diagram of which is shown in FIG. 2. In other words, let us calculate in advance the values of the total permissible active loads for cases of disconnection of an inoperative or inoperable GA (Ptot.add.off 1, Ptot.add.off 2 ... Ptot.add.off.i ... Ptot.add.off 19 ) for the whole number of controlled modes of NPP operation:

1. Rsum.dop.otk.1 = 200kW - only GA1 works and it is efficient;

2. Rsum.dop.otkl.2 = 160 kW - only GA2 works and it is efficient;

3. Rsum.dop.otkl.3 = 80 kW - only GA3 works and it is efficient;

4. Rsum.dop.otkl.4 = 360 kW - GA1 and GA2 are working and they are all operational;

5. Rsum.dop.otkl.5 = 280 kW - GA1 and GA3 work and they are all operational;

6. Rsum.dop.otkl.6 = 240 kW - GA2 and GA3 work and they are all operational;

7. Rsum.dop.otkl.7 = 440 kW - GA1, GA2 and GA3 work and they are all operational;

8. Rsum.dop.otkl.8 = 160 kW - GA1 and GA2 work, while GA2 is efficient, and GA1 is not;

9. Rsum.dop.otkl.9 = 200 kW - GA1 and GA2 work, while GA1 is efficient, and GA2 is not;

10. Rsum.dop.otkl.10 = 80 kW - GA1 and GA3 work, while GA3 is operational, and GA1 is not;

11. Rsum.dop.otkl.11 = 200 kW - GA1 and GA3 are working, while GA1 is operational, and GA3 is not;

12. Rsum.dop.otkl.12 = 80 kW - GA2 and GA3 work, while GA3 is operational, and GA2 is not;

13. Rsum.dop.otkl.13 = 160 kW - GA2 and GA3 work, while GA2 is operational, and GA3 is not;

14. Rsum.dop.otkl.14 = 240 kW - GA1, GA2 and GA3 are working, while GA2 and GA3 are efficient, but GA1 is not;

15. Rsum.dop.otkl.15 = 280 kW - GA1, GA2 and GA3 work, while GA1 and GA3 are efficient, but GA2 is not;

16. Rsum.dop.otkl.16 = 360 kW - GA1, GA2 and GA3 work, while GA1 and GA2 are efficient, but GA3 is not;

17. Rsum.dop.otkl.17 = 80 kW - GA1, GA2 and GA3 work, while GA3 is operational, and GA1 and GA2 are not;

18. Rsum.dop.otkl.18 = 160 kW - GA1, GA2 and GA3 are working, while GA2 is operational, and GA1 and GA3 are not;

19. Rsum.dop.otkl.19 = 200 kW - GA1, GA2 and GA3 work, while GA1 is operational, and GA2 and GA2 are not.

Suppose that two units are operating in the NPP - GA2 and GA3, and GA1 is in reserve and is not connected to the network. Let us assume that the network load is 210 kW (P2 = 140 kW, P3 = 70 kW) and at this moment the diesel cooling system of the third unit failed and GA3 went into an inoperative state.

In this case:

at the output of the unit for monitoring the operation of GA1 (2.1 in Fig. 1) there is a logical "0" signal, which is fed to the first of the first inputs of the unit for determining the operating mode of the AEES 5;

at the outputs of the units for monitoring the operation of GA2 and GA3 (2.2 and 2.3, respectively), a logical “1” signal is generated and fed to the second and third of the first inputs of the unit for determining the mode of operation of the NPP 5;

at the outputs of the units for monitoring the technical state of GA1 and GA2 (3.1 and 3.2, respectively), a logical "0" signal is stored, which is fed to the corresponding first and second of the second inputs of the unit for determining the mode of operation of the NPP 5;

at the output of the unit for monitoring the technical state of GA3, a logical “1” signal is generated and fed to the third of the second inputs of the unit for determining the mode of operation of the NPP 5.

The logical "1" signal from the second of the first inputs of the unit for determining the operating mode of the AEES 5 is fed to the first input of the logical element "AND" 11.6 (Fig. 2). From the third of the first inputs of the unit for determining the mode of functioning of the AEES 5 (Fig. 1), the logical signal "1" is fed to the second input of the logical element "AND" 11.6 (Fig. 2). The logical "0" signal from the first of the first inputs of block 5 (Fig. 1) is fed to the input of the logical element "NOT" 12.1 (Fig. 2), at the output of which the logical "1" signal appears and is fed to the third input of the logical element "AND "11.6. Since all three inputs of the logical element "AND" 11.6 received a signal of a logical "1", then at its output there is also a signal of a logical "1", which is fed to the first input of the logical element "AND" 11.24. The logical "0" signal from the second of the second inputs of block 5 (Fig. 1) is fed to the input of the logical element "NOT" 12.5 (Fig. 2), at the output of which the logical "1" signal appears and is fed to the second input of the logical element "AND "11.24. The logical "1" signal from the third input of block 5 is fed to the third input of the logical element "AND" 11.24. Since all three inputs of the logical element "AND" 11.24 received a signal of logical "1", then at its output, and therefore at the thirteenth of the first outputs of block 5 (Fig. 1), a signal of logical "1" is generated. The appearance of a logical "1" signal at the thirteenth of the first outputs of block 5 identifies the AEES operation mode as an operation mode in which HA2 and HA3 operate and HA3 has passed into an inoperative state, but still performs its functions.

The logical "1" signal from the thirteenth of the first outputs of the unit for determining the operating mode of the NPP 5 (Fig. 1) is fed to the control input of the corresponding controlled key 7.13 to the input, which receives a signal from the 6.13 memory unit corresponding to the permissible load value in this operating mode (proportional the value of the total permissible active load of the NPP for cases of disconnection of an inoperative or inoperative GA, corresponding to the 13th mode of operation) Ptot.add.off 13 = 160 kW. The controlled switch 7.13 opens and a signal proportional to Ptotal allowable off 13 = 160 kW passes to its output and goes to the second input of the comparison unit 8.

Thus, during the transition of one of the GAs to an inoperative state, the operating mode of the NPP was determined in this case as a mode in which GA2 and GA3 operate as part of the NPP and at the same time GA3 passed into an inoperative state, but still continues to work, and selected from the values calculated in advance total permissible active loads for cases of disconnection of an inoperative or inoperative HA (Ptot.add.off 1, Ptot.add.off 2 ... Ptot.add.off.i ... Ptot.add.off 19) the value corresponding to this mode (Psum .add. off 13 = 160kW).

In this case, signals proportional to the load of the second and third units from the outputs of the active load sensors 1.2 and 1.3 (Fig. 1) are fed to the second and third inputs of the addition unit 4, respectively. At the output of the addition block 4, a signal is generated proportional to the active load of the NPP network for a given operating mode Psum13 = 210 kW and is fed to the first input of the comparison unit 8. In block 8, the signals arriving at its first and second inputs are compared and, since the signal to the first input is more than the second (210kW> 160 kW), then a logical "1" signal appears at the output of unit 8, informing about the need to unload the NPP. This signal is fed to the first input of the logical element "OR" 9, at its output a logical "1" signal is also generated, which is transmitted to the input of the block for disconnecting some of the consumers 10. NPP preventive unloading operation.

Thus, in the course of operation, the operations were performed to determine the value of the current total load of the NPP (Рsum13 = 210 kW) and compare it with the value of the total permissible active load for the case of disconnecting an inoperative HA (Рsum.add.off 13 = 160 kW) and since the value the current value of the load turned out to be greater than Ptot.add.off.13, then the operation of unloading the NPP was performed by disconnecting part of the load.

The proposed invention was created in the process of developing a prototype device for preventive unloading of an autonomous electric power system, carried out by the author on his own initiative. Calculations were performed and a working model of a device that implements the inventive method was made, laboratory tests of which showed the possibility of using this method in autonomous electric power plants, which, taking into account the above, makes it possible to conclude about the possibility of its industrial application.

Claims (2)

1. A method of preventive unloading of an autonomous electric power system (AEES), according to which, when one or more generator sets (GA) fail, the mode is determined in which the NPP operates, characterized by the composition of the working, as well as those that have passed into an inoperative state, but continue to work. and corresponding to this mode is selected the total value active load allowable for the cases of inoperable or inefficient disable HA _{(sum.dop.otkl.i} P) from the number of allowable values of total active loads for disabling cases unworkable or inoperative GA (P _{summ.dop.otkl .1} , Р _sum.add.dev . ₂ ... Р _{sum.add.dev.i} ... P _sum.add.dev. AEES at a given time (P _{total i} ), compare the calculated value of P _{total i} with the permissible value of P _total allowable _{deviation i} and at P _{total i} > P _{sum.add.off i} form a signal to turn off some of the consumers of electrical energy until the inoperable HA is turned off. 2. The method according to claim 1, characterized in that for its implementation a device is used, which contains, according to the number of HA: active load sensors, control units of the corresponding HA, blocks for determining the technical state of the corresponding HA; as well as an addition unit, a unit for determining the NPP operation mode; by the number of controlled NPP operation modes: memory blocks, controlled keys; and, in addition, a comparison unit, an OR gate and a consumer disconnect unit; the outputs of the active load sensors are connected to the corresponding inputs of the addition unit, the output of which is connected to the first input of the comparison unit; the output of each of the operation control units is connected to the corresponding of the first inputs of the unit for determining the operating mode of the NPP, the output of each of the units for determining the technical condition is connected to the corresponding of the second inputs of the unit for determining the operating mode of the NPP, each of the first outputs of which is connected to the control input of the corresponding controlled key; the output of each of the memory blocks is connected to the information input of the corresponding controlled key, the output of each of which is connected to the second input of the comparison unit; the output of the comparison unit is connected to the first input of the "OR" logic element, the second output of the unit for determining the operating mode of the NPP is connected to the second input of the "OR" logic element, the output of which is connected to the input of the consumer disconnect unit, the output of the consumer disconnection unit is the device output.

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