RU2742817C1 - Device for preventive control of generator unit switching off - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: use: in electrical engineering for preventive control of generator set (GS) disconnection in order to protect, for example, ship electric power systems (SEPS) against overload caused by erroneous actions of crew. Device comprises a GS signal disconnection signal generating unit based on the number GS: active load sensors and operation sensors, as well as a control unit for the technical state of the disconnected GS, a single -vibrator, a unit for addition, unit for generating active load of ship electric power system (SEPS) after disconnection of disconnected GS, comparator unit, logic unit, signaling unit, consumer disconnection unit and GS disconnection unit; wherein output of GS signal disconnection unit is connected to univibrator input, output of each of active load sensors is connected to corresponding input of addition unit, output of which is connected to first input of comparator unit; output of each of operation sensors GS is connected to corresponding of first inputs of unit of formation of allowable value of active load SEPS after disconnection of disconnected GS, output of which is connected to second input of comparator unit; output of technical condition control unit of disconnected GS is connected to second input of logic unit; output of monostable multivibrator is connected to second input of SEPS active load permissible value generating unit after disconnection of disconnected GS and to third input of logic unit; output of comparison unit is connected to first input of logic unit, first output of which is connected to input of GS disconnection unit, second output of logic unit is connected to alarm unit, third output of logic unit is connected to input of consumer disconnection unit, in contrast to the prototype, additionally comprises units for monitoring the technical state of the generator units operating in parallel to the disconnected GS, and the logic unit has additional fourth inputs, wherein the output of each of the control units of the technical state of the generator units operating in parallel to the disconnected GS is connected to the corresponding of the fourth inputs of the logic unit.

EFFECT: higher safety of GS disconnection.

1 cl, 2 dwg

Description

The invention relates to the field of electrical engineering and can be used for preventive control of the shutdown of a generator set (GA) in order to protect, for example, ship electric power systems (SEES) from overload caused by erroneous actions of the crew.

There is a known method of protecting the network of an autonomous power plant (according to Patent RU 2681201 C1, publ. 03/05/2019) by turning off an inoperative HA, in which technical parameters are measured that characterize the power generated by each of the HA, operating in parallel, based on the measurements, the point in time is determined when one from the GA turns out to be inoperative and at the same time switches to the motor mode of operation, and this GA is disconnected from the network.

This method allows you to turn off the GA in a timely manner before the network is overloaded with reverse power, providing preventive control of the SEES. But the method is designed to disable only a known inoperable GA.

The closest to the one proposed and selected by the author for the prototype is a device that implements the method of preventive control of the GA shutdown (patent for invention RU 2 731 756, published 09/08/2020) according to which a command is generated to shutdown (stop) the GA, analyze the mode of operation of the ship's electric power systems (SEES), and if the SEES operates in a mode in which the shutdown of the GA will lead to an emergency caused by the loading of at least one of the GAs remaining in operation above the permissible value, then a control action is formed aimed at preventing this emergency. The device, taken as a prototype, contains a block for generating a signal to turn off the HPS, a block for analyzing the operating mode of the SEES and preventing an emergency and a block for turning off the HA, while the output of the signal generating unit is connected to the input of the block for analyzing the operating mode of the SEES and preventing an emergency, the output of which is connected with the input of the GA switch-off unit; at the same time, the unit for analyzing the operating mode of the SEES and preventing an emergency situation (hereinafter referred to as the “analysis unit”) contains, according to the number of GAs: active load sensors and GA operation sensors, as well as a unit for monitoring the technical state of the GA to be switched off, a one-shot, an addition unit, a unit for forming an admissible value SEES active load after switching off the switched off HA, comparison unit, logical unit, alarm unit and consumer disconnection unit; when this 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 outputs of the GA operation sensors are connected to the corresponding from the first inputs of the unit for forming the permissible value of the active load of the SEES after the disconnected GA, the output of which is connected to the second input of the comparison unit; the output of the unit for monitoring the technical state of the disconnected HA is connected to the second input of the logic unit; the input of the one-shot is the input of the analysis unit, the output of the one-shot is connected to the second input of the unit for forming the permissible value of the active load of the SEES after disconnecting the switched off GA and to the third input of the logical block; the output of the comparison unit is connected to the first input of the logical block, the first output of which is the output of the analysis block, the second output of the logical block is connected to the input of the signaling unit, the third output of the logical block is connected to the input of the consumer disconnecting unit.

The disadvantage of the device is the commission of erroneous actions in the event of an inoperative state of at least one of the parallel operating HA at the time of the formation of a command to turn off (stop) the switched off HA, which can lead to unjustified disconnection of consumers, leading to disruption of technological processes on the vessel, which is especially undesirable for fishing vessels engaged in the extraction, processing and storage of fish and vessels of the technical fleet, as well as floating drilling platforms.

The inventive device makes it possible to increase the safety of disconnecting the disconnected HA by eliminating erroneous actions arising from the failure of units operating in parallel with the disconnected (stopped) HA at the moment of generating a signal to turn it off (stop).

To achieve the specified technical result, a device for preventive control of a generator set shutdown, which, like the prototype, contains a signal generating unit for shutting down the GA, according to the number of GAs: active load sensors and operation sensors, as well as a unit for monitoring the technical state of the GA to be shut off, a one-shot, an addition block, a block for forming the permissible value of the active load of the ship's electric power system (SEES) after disconnecting the switched-off HA, a comparison block, a logical block, an alarm block, a block for switching off consumers and a block for turning off the HA while the output of the signal generation unit to turn off the GA is connected to the input of the one-shot, the output of each of the active load sensors is connected to the corresponding input of the addition unit, the output of which is connected to the first input of the comparison unit; the output of each of the GA operation sensors is connected to the corresponding of the first inputs of the unit for forming the permissible value of the active load of the SEES after the disconnected GA, the output of which is connected to the second input of the comparison unit; the output of the unit for monitoring the technical state of the disconnected HA is connected to the second input of the logic unit; the output of the one-shot is connected to the second input of the unit for forming the permissible value of the active load of the SEES after disconnecting the switched off HA and with the third input of the logic block; the output of the comparison unit is connected to the first input of the logical block, the first output of which is connected to the input of the GA shutdown block, the second output of the logical block is connected to the signaling unit, the third output of the logical block is connected to the input of the consumer shutdown block, unlike the prototype, additionally contains technical control units the state of the generator sets operating in parallel with the switched off HA, and the logical block has additional fourth inputs, while the output of each of the blocks for monitoring the technical state of the generator sets operating in parallel with the switched off HA is connected to the corresponding of the fourth inputs of the logical block.

In this case, the logical block additionally contains a logical element "AND", a logical element "NOT" and two logical elements "OR" and connections between them and other functional blocks, forming a new set of features. The essence of the invention lies in the fact that the proposed device, when the HA is turned off, takes into account, in contrast to the prototype, the technical condition of the generating sets operating in parallel with the switched off HA. If the signal to turn off (stop) the HA occurs when the network load is less than the maximum allowable in the operable technical state of the HA being switched off, then the device, taken as a prototype, will turn off (stop) this unit. This is true if the rest of the generating sets operating in parallel with the switched off GA are also operational. However, if at least one of them is in an inoperative state, then shutting down the HA in this situation is undesirable, since if it is necessary to turn off the inoperative unit, the network will be overloaded or some consumers will need to be disconnected. To avoid such errors, you should block the shutdown of the GA with the issuance of information to the maintenance personnel about erroneous actions.

Comparison of the proposed method and the prototype showed that the task - to increase the safety of HA shutdown by eliminating errors associated with illegal actions of the service personnel (human factor) - 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 drawing (Fig. 1) shows a functional diagram of the proposed device for an electric power system with n parallel generating sets. The device (Fig. 1) contains: a block for generating a signal to turn off the HA 1, according to the number of HA: active load sensors 2.1, 2.2 ... 2.n and operation sensors HA3.1, 3.2 ... 3.n, as well as a block for monitoring the technical state of the switched off GA 4, one-shot 5, units for monitoring the technical condition of generating sets operating in parallel with the disconnected GA 6.1,6.2 ... 6.k, addition unit 7, unit for forming the permissible value of the active load of SEES after disconnecting the disconnected GA 8, comparison unit 9, logical unit 10 , an alarm unit 11, a consumer shutdown unit 12 and a HA shutdown unit 13; while the output of the signal generation unit to turn off the GA 1 is connected to the input of the one-shot 5, the output of each of the active load sensors 2.1, 2.2 ... 2.n is connected to the corresponding input of the addition unit 7, the output of which is connected to the first input of the comparison unit 9; the output of each of the GA3.1, 3.2 ... 3.n operation sensors is connected to the corresponding of the first inputs of the unit for forming the permissible value of the active load of the SEES after disconnecting the switched off GA 8, the output of which is connected to the second input of the comparison unit 9; the output of the unit for monitoring the technical condition of the disconnected HA 4 is connected to the second input of the logic unit 10; the output of the one-shot 5 is connected to the second input of the unit for forming the permissible value of the active load of the SEES after disconnecting the switched off GA 8 and with the third input of the logical unit 10; the output of the comparison unit 9 is connected to the first input of the logical unit 10, the first output of which is connected to the input of the GA switch-off unit 13, the output of each of the units for monitoring the technical condition of the generating sets operating in parallel with the switched-off GA 6.1,6.2 ... 6k is connected to the corresponding of the fourth inputs logic unit 10, the second output of which is connected to the signaling unit 11, the third output of the logic unit 10 is connected to the input of the consumer disconnect unit 12.

The unit for generating a signal to turn off the GA 1, active load sensors 2.1, 2.2 ... 2.n and sensors for the operation of GA3.1, 3.2 ... 3.n, a unit for monitoring the technical condition of the GA to be switched off 4, a one-shot 5,, an addition unit 7, a unit for forming an acceptable the values of the active load of the SEES after disconnecting the disconnected GA 8, the comparison unit 9, the signaling unit 11, the consumer disconnection unit 12 and the GA disconnection unit 13 are known functional blocks, similar to the corresponding blocks used in the device taken as a prototype.

Blocks for monitoring the technical condition of generating sets operating in parallel with the switched off GA 6.1,6.2 ... 6.k - known functional blocks, each of which at its output generates a logic "1" signal in the event of failure of the corresponding GA and a logic "0" signal otherwise. The number of these units for SEES with n GAs operating in parallel is equal to k. Moreover, k = n-1. These blocks are identical to the block for monitoring the technical condition of the switched off GA used in the prototype.

Logic block 10 is a new functional block that provides blocking of the shutdown of the switched off HA in the event that a signal is supplied to turn off (stop) the HA occurs when the network load is less than the maximum permissible and the operational technical state of the switched off HA, but at least one of the generating sets is inoperative, working in parallel with the switched off GA. Figure 2 shows one of the possible practical implementations of the logic unit 10 (Figure 1). The logical block (Fig. 2) contains the first and second logical elements "NOT" 14 and 15, respectively, the delay block 16, the first logical gate "OR" 17, the first and second logical elements "AND" 18 and 19, respectively, the second logical gate " OR "20, the third gate" AND "21, the third gate" NOT "22, the fourth gate" AND "23, the fourth gate" OR "24 and the fifth gate" AND "25, and the first input of the logic block is connected with the input of the first logical element "NOT" 14, the first input of the first logical element "AND" 18 and the first input of the second logical element "AND" 19; the second input of the logical block is connected to the second input of the first logical element "AND" 18 and the input of the second logical element "NOT" 15; the third input of the logical block is connected to the input of the delay block 16, the third input of the second logical element "AND" 19, the third input of the third logical element "AND" 21 and the second input of the fifth logical element "AND" 25; the fourth inputs of the logical block are connected to the corresponding inputs of the first logical element "OR" 17, the output of which is connected to the fourth input of the third logical gate "AND" 21, the output of the first logical gate "NOT" 14 is connected to the first input of the third logical gate "AND" 21 and the first input of the second logical element "OR" 20, the output of which is connected to the first input of the fourth logical element "AND" 23, the output of the first logical element "AND" 18 is connected to the second input of the first logical element "OR" 20 and the first input of the fifth logical element " AND "25, the output of the second logical element" NOT "15 is connected to the second input of the third logical element" AND "21 and to the second input of the second logical element" AND "19, the output of which is connected to the second input of the fourth logical element" OR "24, the output delay block 16 is connected to the third input of the fourth logical element "AND" 23, the output of which is connected to the first output of the logical block, the output of the third l Logic element "AND" 21 is connected to the input of the third logical element "NOT" 22 and the first input of the fourth logical element "OR" 24, the output of which is connected to the second output of the logic block. The output of the third logical element "NOT" 22 is connected to the second input of the fourth logical element "AND" 23, the output of the fifth logical element "AND" 25 is connected to the third output of the logical block.

The logical block, the functional diagram of which is shown in Fig. 2, operates as follows.

When a logical zero signal arrives at the third input of the logical block, a logical zero signal is stored at the output of the delay block and is fed to the third input of the fourth logical element "AND" 23, at its output and the first output of the logical block is a logical zero signal. From the third input of the logical block, the logical zero signal is fed to the third input of the second logical element "AND" 19, the third input of the third logical element "AND" 21 and the second input of the fifth logical element "AND" 25. At the same time, at the outputs of the second, third and fifth logical elements "AND" 19,21 and 25, respectively - a signal of logical zero. The logical zero signal from the output of the second logical element "AND" 19 is fed to the second input of the fourth logical gate "OR" 24, the first input of which receives a logical zero signal from the output of the third logical gate "AND" 21. Since both inputs of the fourth logical gate "OR" 24 a logical zero signal arrives, then at its output and the second output of the logical block is also a logical zero signal. Since the second input of the fifth logical element "AND" receives a signal of logical zero, then at its output and the third output of the logical block there is also a signal of logical zero. Thus, when a logical zero signal arrives at the third input of a logical block, all three outputs are a logical "0" signal.

If a logical "1" signal arrives at the third input of the logical block, and a logical zero signal arrives at the first, second and fourth inputs, then the logical zero signal goes to the input of the first logical element "NOT" 14, at the output of which a logical "1" signal appears and arrives at the first input of the second logical element "OR" 20, At the output of the second logical element "OR" 20, a logical signal "1" appears and is fed to the first input of the fourth logical gate "AND" 23. The signal of logical "0" is fed to the first and the second inputs of the first logical element "AND" 18, at the output of which there is a logical zero signal arriving at the first input of the fifth logical element "AND" 25. At the output of the fifth logical element "AND" 25 and the third output of the logical block - a signal of logical "0" ... The logical zero signal arrives at the first input of the second logical element "AND" 19, at its output - a logical zero signal arriving at the second input of the fourth logical gate "OR" 24. The logical zero signal arrives at each of the inputs of the first logical gate "OR" 17 , at the output of which - a signal of logical "0", which is fed to the fourth input of the third logical element "AND" 21. At the output of the third logical element "AND" 21, a logical zero signal is stored and is fed to the input of the third logical element "NOT" 22 and the first the input of the fourth logical element "OR" 24, at the output of which and the second output of the logical block - a signal of logical zero. Since the input of the third logical element "NOT" 22 received a logical zero signal, its output is a logical "1" signal, which is fed to the second input of the fourth logical "AND" element 23. The logical "1" signal is fed to the input of the delay unit 16 and after a time delay t ₂ appears at its output and enters the third input of the fourth logical element "AND" 23. The value of the time delay t ₂ is determined by the time required to turn off the disconnected consumers when unloading the SEES and usually does not exceed 1 second. In this case, the duration of the logical "1" signal at the output of the one-shot t ₁ must exceed the time delay of the delay unit and can be, for example, 2 seconds. Since all three inputs of the logical element "AND" 23 received a logical "1" signal, then a logical "1" signal is generated at its output and the first output of the logical block. Thus, if a logical "1" signal is received at the third input of a logical block, and a logical "0" signal is received at all its other inputs, then a logical "1" signal appears at the first output of a logical block, and a signal appears at its second and third outputs logical "0".

If, when a logical "1" signal arrives at the third input of a logical block, at least one of its fourth inputs receives a logical "1" signal, and a logical "0" signal is sent to the first and second inputs, then a logical "1" signal is sent to one from the inputs of the first logical element "OR" 17, at the output of which and the fourth input of the third logical element "AND" 21, a logical signal "1" appears. The logical zero signal is fed to the input of the first logical element "NOT" 14, at the output of which and the first input of the third logical gate "AND" 21 a logical "1" signal appears. The logical zero signal is fed to the first and second inputs of the first logical element "AND" 18, at its output and the first input of the fifth logical element "AND" 25 - a logical "0" signal. Since the first input of the fifth logical element "AND" 25 received a signal of logical "0", then at its output and the third output of the logical block - a signal of logical zero. The logical zero signal is fed to the input of the second logical element "NOT" 15, at the output of which and the second input of the third logical element "AND" 21 a logical signal "1" appears. The logical "1" signal from the third input of the logical block goes to the third input of the third logical element "AND" 21. Since all four inputs of the third logical gate "AND" 21 received a signal of the logical "1", then at its output, the input of the third logical gate " NOT "22 and the first input of the fourth logical element" OR "24, a logical" 1 "signal appears. Since the first input of the fourth logical element "OR" 24 receives a logical "1" signal, then a logical "1" signal is fixed at its output and the second output of the logical block. When a logical “1” signal arrives at the input of the third logical element “NOT” 22, a logical “0” signal appears at its output and goes to the second input of the fourth logical element “AND” 23. Since the second input of the fourth logical element “AND” 23 a logical "0" signal is received, then at its output and the first output of the logical block - a logical zero signal. Thus, if a logical "1" signal arrives at the third and at least one of the fourth inputs of the logical block, and a logical "0" signal is received at its first and second inputs, then the logical "0" signal is fixed at the first and third outputs of the logical block , and at its second output - a logical "1" signal.

If, when a logical "1" signal arrives at the third input of a logical block, a logical "1" signal is received at its first input, and a logical "0" signal is sent to the second and fourth inputs, then a logical "1" signal is sent to the input of the first logical element " NOT "14, at the output of which and the first input of the second logical element" OR "20 a logical" 0 "signal appears. Since the second input of the first logical element "AND" 18 receives a logical zero signal, then at its output, the second input of the second logical element "OR" 20 and the first input of the fifth logical gate "AND" 25 - a signal of logical "0". At the output of the fifth logical element "AND" 25 and the third output of the logical block, a logical "0" signal is recorded. Since both inputs of the second logical element "OR" 20 received signals of logical zero, then at its output and the first input of the fourth logical element "AND" 23 - also a signal of logical "0". At the output of the fourth logical element "AND" 23 and the first output of the logical block, a logical "0" signal is recorded. The logical zero signal from the second input of the logical block is fed to the input of the second logical element "NOT" 15, at the output of which and at the second input of the second logical gate "AND" 19 a logical signal "1" appears. The logical "1" signal from the first and third inputs of the logical block is fed, respectively, to the first and third inputs of the second logical element "AND" 19. Since all three inputs of the second logical element "AND" 19 received a logical "1" signal, then at its output and the second input of the fourth logical gate "OR" 24 there is also a logical "1" signal. Since the second input of the fourth logical element "OR" 24 received a logical "1" signal, then a logical "1" signal also appears at its output and the second output of the logical block. Thus, when a logical "1" signal arrives at the first and third inputs of a logical block and a logical "0" signal to the second and fourth inputs of a logical block, at its first and third outputs - a logical "0" signal, and at its second output - a signal logical "1".

If, when a logical "1" signal arrives at the third input of a logical block, a logical "1" signal is received at its second input, and a logical "0" signal is sent to the first and fourth inputs, then a logical "1" signal is fed to the input of the second logical element " NOT "15, at the output of which a logical zero signal appears and is fed to the second inputs of the second and third logical elements" AND "19 and 21, respectively. At the output of the second logical element "AND" 19 and the second input of the fourth logical element "OR" 24 - a logical zero signal. At the output of the third logical element "AND" 21, the input of the third logical element "NOT" 22 and the first input of the fourth logical element "OR" 24 - a logical zero signal. Since both inputs of the fourth logical element "OR" 24 receive a logical zero signal, a logical "0" signal is fixed at its output and the second output of the logical block. Since the input of the third logical element "NOT" 22 receives a signal of logical zero, then at its output and the second input of the fourth logical element "AND" 23 - a signal of logical "1". The logical zero signal is fed to the input of the first logical element "NOT" 14, at the output of which a logical "1" signal appears and is fed to the first input of the second logical element "OR" 20. At the output of the second logical element "OR" 20, the logical signal "1" appears "And arrives at the first input of the fourth logical element" AND "23. The logical" 1 "signal arrives at the input of the delay block 16 and after a time delay appears at its output and the third input of the fourth logical element" AND "23. Since all three inputs the fourth logical block "AND" 23 received a logical "1" signal, then a logical "1" signal appears at its output and the first output of the logical block. The logical zero signal is fed to the first input of the first logical element "AND" 18, at its output and the first input of the fifth logical element "AND" 25 - the logical "0" signal. Since a logical zero signal arrives at the first input of the fifth logical element "AND" 25, a logical "0" signal is fixed at its output and the third output of the logical block. Thus, if, when a logical "1" signal arrives at the third input of a logical block, a logical "1" signal arrives at its second input, and a logical "0" signal is sent to the first and fourth inputs, then a logical " 1 ", and on its second and third outputs - a logical" 0 "signal.

If, when a logical "1" signal arrives at the third input of a logical block, a logical "1" signal is sent to its first and second inputs, and a logical "0" signal is sent to all fourth inputs, then a logical "1" signal is sent to the input of the first logical element "NOT" 14, at the output of which and the first input of the third logical element "AND" 21, a logical zero signal appears. In this case, at the output of the third logical element "AND" 21, the input of the third logical element "NOT" 22 and the first input of the fourth logical element "OR" 24, a logical zero signal appears. At the output of the third logical element "NOT" 22, a logical "1" signal appears and is fed to the second input of the fourth logical gate "AND" 23. The logical "1" signal is fed to the first and second inputs of the first logical gate "AND" 18, at the output of which , the second input of the second logical block "OR" 20 and the first input of the fifth logical element "AND" 25, a logical signal "1" is generated. At the output of the second logical element "OR" 20 and the first input of the fourth logical element "AND" 23, a logical "1" signal appears. The logical "1" signal from the third input of the logical block is fed to the input of the delay block 16 and to the second input of the fifth logical element "AND" 25, at the output of which and the third output of the logical block a logical "1" signal is generated. After a time delay, the logical "1" signal appears at the output of the delay unit 16 and is fed to the third input of the fourth logical element "AND" 23. Since all three inputs of the fourth logical element "AND" 23 received a logical "1" signal, then it the output and the first output of the logical block appears a logical "1" signal. The logical "1" signal is fed to the input of the second logical element "NOT" 15, at the output of which and the second input of the second logical element "AND" 19, a logical zero signal appears. At the output of the second logical element "AND" 19 and the second input of the fourth logical element "OR" 24 - a logical zero signal. Since a logical zero signal is supplied to both inputs of the fourth logical element "OR" 24, a logical zero signal is fixed at its output and the second output of the logical block. Thus, if, when a logical "1" signal arrives at the third input of a logical block, a logical "1" signal arrives at its first and second inputs, and a logical "0" signal is sent to all fourth inputs, then at the first and third outputs of the logical block - a logical "1" signal, and at the second output - a logical zero signal.

If, when a logical "1" signal arrives at the third input of a logical block, its first and second inputs, as well as at least one of the fourth inputs, a logical "1" signal is received, then a logical "1" signal will be sent to at least one of the inputs the first logical element "OR" 17, at the output of which and at the fourth input of the third logical element "AND" 21, a signal of logical "1" will appear. However, at the output of the third logical gate "AND" 21, a signal of logical zero will remain, since its first input a logical zero signal will be received from the output of the first logical element "NOT" 14. In general, when signals of a logical "1" arrive at the first, second and third inputs of the logical block, the circuit works the same as in the previous case, regardless of the signals arriving at the fourth inputs. Thus, if, when a logical "1" signal arrives at the third input of a logical block, a logical "1" signal is received at its first and second inputs, as well as at least one of the fourth inputs, then a logical signal is received at the first and third outputs of the logical block. "1", and the second output is a logical zero signal.

If, when a logical "1" signal arrives at the third input of a logical block, a logical "1" signal is received at its first, as well as at least one of the fourth inputs, and a logical "0" signal is sent to the second input, then the logical "1" signal will arrive at at least one of the inputs of the first logical element "OR" 17, at the output of which and at the fourth input of the third logical element "AND" 21, a logical "1" signal will appear, but at its output the logical zero signal will remain, since the first the input of the third logical element "AND" 21 receives a logical zero signal from the output of the first logical gate "NOT" 14. In this regard, the circuit works the same as in the case when the signal of logical "1" arrives only at the first and third inputs of the logical block. Thus, if, when a logical "1" signal arrives at the third input of a logical block, a logical "1" signal is received at its first, as well as at least one of the fourth inputs, and a logical "0" signal is sent to the second input, then at the second the output of the logical block generates a logical "1" signal, and at the first and third outputs - a logical zero signal.

If, when a logical "1" signal arrives at the third input of a logical block, a logical "1" signal is received at its second, as well as at least one of the fourth inputs, and a logical "0" signal is sent to the first input, then the logical "1" signal will arrive at at least one of the inputs of the first logical element "OR" 17, at the output of which and at the fourth input of the third logical element "AND" 21, a logical "1" signal will appear, but at its output the logical zero signal will remain, since the second the input of the third logical element "AND" 21 receives a logical zero signal from the output of the second logical element "NOT" 15.

In this regard, the circuit works in the same way as in the case when the logic "1" signal arrives only at the second and third inputs of the logic block. Thus, if, when a logical "1" signal arrives at the third input of a logical block, a logical "1" signal is received at its second, as well as at least one of the fourth inputs, and a logical "0" signal is sent to the first input, then at the first the output of the logical block generates a signal of logical "1", and at the second and third outputs - a signal of logical zero.

The device for preventive control of the shutdown of the generating set, the functional diagram of which is shown in Fig. 1, operates as follows.

In the initial state, signals proportional to the active load of each of the operating HA from the outputs of active load sensors 2.1, 2.2 ... 2.n are fed to the corresponding inputs of the addition unit 7, at the output of which a signal appears proportional to the total load of the SEES at a given time (P1). This signal is fed to the first input of the comparison unit 9. The GA operation sensors 3.1, 3.2 ... 3.n form logical "1" signals at their outputs, if the corresponding GA is working and transmit this information to the corresponding first inputs of the unit for generating the permissible active load value of the SEES after disconnecting the switched off GA 8, at the output of which a signal is generated, proportional to the total permissible load of all operating GA (P2). This signal is fed to the second input of the comparison unit 9. If there is no overload, then the output of block 9 is a logical "0" signal, but at all outputs of the logical block 10 there is a logical "0" signal, since at its third input there is a logical " 0 ".

In the case of a signal to turn off (stop) the switched off HA (for example, when you press the "Stop" button of the remote automated control system (DAU) of the generator set), a logical "1" signal appears at the output of the signal conditioning unit to turn off the HA 1, which will go to the input one-shot 5, at the output of which there will be a signal of logical "1" of a given duration t ₂ . This signal will go to the third input of block 8, at the output of which a signal appears proportional to the permissible value of the active load of the SEES after disconnecting the switched off GA (P2). Signal P2 is fed to the second input of the comparison unit 9 and, if the network load is not large and P1 <P2, then the signal of logical "0" is stored at its output, which is fed to the first input of logical block 10. If all HA operating in parallel are operational, then on the output of the unit for monitoring the technical condition of the disconnected GA 4 and all outputs of the units for monitoring the technical condition of the generating sets operating in parallel with the disconnected GA 6.1,6.2 ... 6.k is a logical zero signal that goes to the second and all fourth inputs of logic block 10. Since the third input of the logical block 10 receives a logical "1" signal from the output of the one-shot 5, then at its first output a logical "1" signal is generated, which is fed to the input of the GA switch-off unit 13, the switched-off GA is turned off (stopped). The GA switch-off signal is not blocked. On the second and third outputs of the logic block 10 - a signal of logical zero. If at this time at least one of the generating sets operating in parallel with the switched off GA, for example, the g-th, has passed into an inoperative state, then at the output of the corresponding from the blocks for monitoring the technical condition of the generating units operating in parallel with the switched off GA, 6.g the signal of logical "1" and will go to the g-th of the fourth inputs of the logical block 10. Since at the moment the signal of the logical "1" is applied to the third input of the logical block 10, a signal of logical zero is sent to its first and second inputs, and to one of its the fourth inputs receive a logical "1" signal, then at the first and third outputs of the logical block - a logical zero signal, and at its second output - a logical "1" signal, signaling that the unit shutdown is blocked. That is, the signal to turn off the generator to be switched off is blocked, an operable unit is not switched off in the event of a failure of the GA operating in parallel. This is important, since in the event of a failure of one of the operating generating sets, an alarm is triggered and, in extreme situations, the maintenance personnel often pushes the stop button of the wrong GA, turning off the working machine and further aggravating the situation. The proposed invention avoids this error. Additional features of this technical solution lead to a change in the algorithm of the device for preventive control of the shutdown of the generating set, taken as a prototype, and therefore are essential differences of the proposed invention. When using the device, taken as a prototype, the operating unit will shutdown, which will lead to a dangerous situation and when the parameters of the inoperative HA reach a critical value, the disconnected consumers are disconnected, leading to disruption of technological processes on the ship.

In other modes, the proposed device works in the same way as the prototype.

If the load of the SEES is high and at the moment of giving the command to turn off the switched off GA (the logical "1" signal will be generated by block 1 and will be fed to the input of the one-shot 5, at the output of which a logical "1" signal of the specified duration will appear and will be sent to the third input of the logical block 10) it turns out that P1> P2, then a logical "1" signal will appear at the output of the comparison unit 9 and go to the first input of the logical block 10. If the disconnected GA is operational, then at the output of the technical condition monitoring unit of the disconnected GA 4 and the second input of block 10 - logical "0" signal, at the first output of logical block 10 - logical "0" signal, shutdown is blocked. At the second output of the logical unit 10, a logical “1” signal appears, which is fed to the input of the signaling unit 11, which informs the crew about erroneous actions. At the third output of block 10 - a logical "0" signal - disconnection of the disconnected part of consumers does not occur. This will happen regardless of the technical state of the parallel operating HA and signals arriving at the fourth inputs of the logic block 10 from the units for monitoring the technical state of the generating sets operating in parallel with the switched off HA 6.1,6.2… 6.k.

If, when the condition P1> P2 is fulfilled, it turns out that the switched off GA is inoperative, then a logical "1" signal will appear at the output of the control unit of the technical state of the switched off GA 4 and go to the second input of the logical block 10. Since the first, second and third inputs of the logical block 10 will receive a logical "1" signal, then at its third output a logical "1" signal will appear, which will go to the input of the consumer disconnect unit 12. Then the required number of consumers will be disconnected to fulfill the condition P1 <P2. In this case, after a time delay t ₂ , sufficient to turn off the selected groups of consumers, a logical "1" signal also appears at the first output of the logic block 10, blocking of the GA shutdown signal will not occur and the shutdown unit 13 will turn off the unit to be shut down. This will happen regardless of the technical state of the parallel operating HA and signals arriving at the fourth inputs of the logic block 10 from the units for monitoring the technical state of the generating sets operating in parallel with the switched off HA 6.1,6.2… 6.k.

Device operation.

As an example, consider a SEPP with three GAs with a rated power of 100 kW each (Rnom.1 = Rnom.2 = Rnom.3 = 100kW). Let us assume that all HUs are efficient and work, and the SEES load is 180 kW. Suppose that the crew members decided to turn off the GA3 and pressed the "Stop" button of the DAU of the third unit. In this case, the logical “1” signal from the output of the signal generation unit to turn off GA1 (Fig. 1) will be fed to the input of the one-shot 5, at the output of which a logical “1” signal with duration t = 2s will appear and will be sent to the second input of the unit for generating the permissible active value load SEES after disconnecting the switched off GA 8 and the third input of logical block 10. The value of the total load of three GA is equal to 180 kW, therefore, at the output of the addition unit 7 a signal is generated proportional to 180 kW, which will go to the first input of the comparison unit 9. Since the signal is proportional the total permissible load of all operating GAs in the event of GA3 (P2) shutdown in this case will be equal to P2 = (Pnom.1 + Rnom.2 + Rnom.3) - Rnom.3 = 200 kW, then at the output of the unit for forming the permissible active load value SEES, after disconnecting the switched off GA 8, a signal proportional to 200 kW will appear and will be fed to the second input of the comparison unit 9. Since P1 <P2 (180 kW <200 kW), the output of the comparison unit 9 and the first input of logic block 10 will keep the logic zero signal. Since all operating GAs are operational, at the output of the unit for monitoring the technical state of the GA 4 to be switched off and at the outputs of the units for monitoring the technical condition of generating sets operating in parallel with the GA 6.1, 6.2 being switched off, there is a logical "0" signal, which will be sent to the second and the first and second of the fourth inputs of the logical block 10. In this case, a logical "1" signal will appear at the first output of the logical block 10, which will go to the input of the GA switch-off block 13, the third unit will be switched off, the switch-off signal is not blocked. On the second and third outputs of the logic block 10 - a logic "0" signal.

If, under the same conditions, one of the GAs operating in parallel with GA3, for example, the second, fails, then at the output of the second of the blocks for monitoring the technical state of the generating sets operating in parallel with the GA 6.2 to be switched off, a logical "1" signal will appear and will be sent to the second of the fourth the inputs of the logical block 10. In this case, the logical "0" signal will remain at the first and third outputs of the logical block 10, and the logical "1" signal will appear at its second output and the input of the signaling unit 11. The output of block 11 will generate a signal informing the crew about erroneous actions. The GA3 shutdown signal will be blocked, it will not turn off. Consumers will not be disconnected. If after a while the parameters of the inoperative but continuing to operate GA2 reach a critical value and it will be disabled by protection, then two operating units GA1 and GA3 will have 180 kW of load, which is quite acceptable, there will be no overload and disconnection of consumers.

In this case, the use of a device taken as a prototype, which does not take into account the technical condition of the HA, operating in parallel with the disconnected one, will lead to the shutdown of the operable HA3. The load on GA1 and GA2 will be 180 kW. In this case, when the parameters GA2 reach a critical value, the disconnected consumers will be disconnected, for example, in the manner described in the patent for invention RU 2 731 760, publ. 09/08/2020, Bul. No. 25. In this case, it will be possible to avoid an emergency, but almost all consumers will be disconnected, except for those that ensure the safety of the vessel, the operation of the main engine and steering.

The use of the proposed device in comparison with the prototype allows avoiding unjustified disconnection of consumers, leading to disruption of technological processes on the ship, which is especially important for fishing vessels engaged in the production, processing and storage of fish and vessels of the technical fleet, floating drilling platforms.

In other modes, the proposed device works similarly to the device taken as a prototype.

If at the moment of pressing the "Stop" button of the DAU of the third unit, the SEES load was 240 kW, then the signal at the first input of the comparison unit 9 will exceed the signal at its second input (240 kW> 200 kW). In this case, a logical "1" signal will appear at the output of block 9 and the first input of logical block 10. If at the same time the switched off GA3 is operational, and the GA2 working with it in parallel is out of order, then a logical "0" signal will be sent to the second input of logic block 10, and a logic "1" signal will be sent to the second of its fourth inputs. In this case, the GA3 shutdown signal will be blocked, at the first and third outputs of the logical block - a logical zero signal, and at its second output and the input of the signaling unit 11, a logical "1" signal will appear. The output of block 11 will generate a signal informing the crew about erroneous actions. If this had not happened and GA3 shut down, then GA1 and GA2 would have had 240 kW, overload and power outage of the vessel would have occurred.

If under these conditions, at the moment of pressing the Stop button, the DAE of the third unit GA3 is inoperative, and GA1 and GA2 working with it are operable, then a logical “1” signal will be sent to the second input of logic block 10. In this case, at the third, and after a time delay t ₂ = 1 s and at the first outputs of the logic block 10, a logical "1" signal will appear, and at its second output - a logical zero signal. The logical "1" signal from the third output of the logical block 10 will go to the input of the consumer disconnection unit 12, which will disconnect the groups of disconnected consumers. In this case, the network load will decrease to a value that is permissible for the operation of two HUs, for example, up to 180 kW. After the holding time of the delay block 16 (Fig. 2) equal to 1 s, a logical "1" signal will appear at the first output of the logic block and will be fed to the input of the GA switch-off unit, which will turn off GA3. In this mode, the disconnection of the inoperative disconnected HA is not blocked, but is carried out after the disconnection of the disconnected consumers. The GAs remaining in operation will take over 180 kW of load and will not be overloaded.

If at the moment of pressing the "Stop" button of the DAU of the third unit, the SEES load was 240 kW, then the signal at the first input of the comparison unit 9 will exceed the signal at its second input (240 kW> 200 kW). In this case, a logical "1" signal will appear at the output of block 9 and the first input of logical block 10. If, at the same time, the switched-off GA3 and the GA2 working with it in parallel are out of order, then a logical "1" signal will be sent to the second input of the logic block 10 and to the second of its fourth inputs. In this case, at the third, and after a time delay t ₂ = 1 s and at the first outputs of the logic block 10, a logical "1" signal will appear, and at its second output - a logical zero signal. The logical "1" signal from the third output of the logical block 10 will go to the input of the consumer disconnection unit 12, which will disconnect the groups of disconnected consumers. In this case, the load of the network will decrease to the permissible one when two HUs are turned off, for example, up to 80 kW. After the holding time of the delay block 16 (Fig. 2), a logical "1" signal will appear at the first output of the logical block and will be fed to the input of the GA switch-off unit, which will disable GA3. If the technical condition of GA2 continues to deteriorate and at least one of its parameters reaches a critical value, it will be disabled by protection, but no overload will occur.

The proposed invention was created as part of research work carried out at the Department of Electric Drive and Electrical Equipment of Coastal Installations of the State University of Marine and River Fleet named after Admiral S.O. Makarov ". Calculations were made that showed the possibility of using the proposed method in ship power plants and electric power systems, which, taking into account the above, allows us to conclude about the possibility of its industrial application.

Claims (2)

1. A device for preventive control of a generator set (GA) shutdown, containing a block for generating a signal to shutdown a GA, according to the number of GA: active load sensors and operation sensors, as well as a unit for monitoring the technical state of the GA to be disconnected, a one-shot, an addition unit, a block for generating an allowable value active load of the ship's electric power system (SEES) after disconnecting the disconnected HA, a comparison unit, a logic block, an alarm unit, a consumer shutdown unit and a HA shutdown unit; while the output of the signal generation unit to turn off the GA is connected to the input of the one-shot, the output of each of the active load sensors is connected to the corresponding input of the addition unit, the output of which is connected to the first input of the comparison unit; the output of each of the GA operation sensors is connected to the corresponding of the first inputs of the unit for forming the permissible value of the active load of the SEES after the disconnected GA, the output of which is connected to the second input of the comparison unit; the output of the unit for monitoring the technical state of the disconnected HA is connected to the second input of the logic unit; the output of the one-shot is connected to the second input of the unit for forming the permissible value of the active load of the SEES after disconnecting the switched off HA and with the third input of the logic block; the output of the comparison unit is connected to the first input of the logic block, the first output of which is connected to the input of the GA shutdown unit, the second output of the logic block is connected to the signaling unit, the third output of the logic block is connected to the input of the consumer disconnection unit; characterized in that it additionally contains blocks for monitoring the technical state of generating sets operating in parallel with the switched off GA, and the logical block has additional fourth inputs, while the output of each of the units for monitoring the technical state of the generating units operating in parallel with the switched off GA is connected to the corresponding of the fourth logic block inputs. 2. The device according to claim 1, characterized in that the logical block includes the first and second logical elements "NOT", a delay block, the first logical gate "OR", the first and second logical elements "AND", the second logical gate " OR ", the third logical gate" AND ", the third logical gate" NOT ", the fourth logical gate" AND ", the fourth logical gate" OR "and the fifth logical gate" AND ", and the first input of the logical block is connected to the input of the first logical gate" NOT ", the first input of the first logical element" AND "and the first input of the second logical element" AND "; the second input of the logical block is connected to the second input of the first logical element "AND" and the input of the second logical element "NOT"; the third input of the logical block is connected to the input of the delay block, the third input of the second logical element "AND", the third input of the third logical element "AND" and the second input of the fifth logical element "AND"; the fourth inputs of the logical block are connected to the corresponding inputs of the first logical element "OR", the output of which is connected to the fourth input of the third logical gate "AND", the output of the first logical gate "NOT" is connected to the first input of the third logical gate "AND" and the first input of the second logical gate element "OR", the output of which is connected to the first input of the fourth logical element "AND", the output of the first logical element "AND" is connected to the second input of the first logical element "OR" and the first input of the fifth logical element "AND", the output of the second logical element " NOT "is connected to the second input of the third logical element" AND "and to the second input of the second logical element" AND ", the output of which is connected to the second input of the fourth logical element" OR ", the output of the delay unit is connected to the third input of the fourth logical element" AND ", the output of which is connected to the first output of the logical block, the output of the third logical element "AND" is connected to the input tre th logical element "NOT" and the first input of the fourth logical element "OR", the output of which is connected to the second output of the logical block, the output of the third logical element "NOT" is connected to the second input of the fourth logical element "AND", the output of the fifth logical element "AND" connected to the third output of the logic block.

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