SU1406582A1 - Device for checking multichannel system of secondary electric power supply - Google Patents

Abstract

The invention relates to electrical engineering and is intended to control multichannel systems of secondary power supply sources, determine the nature of the malfunction, the number of the faulty channel and automatically disconnect from the network of the faulty channel or switch it to the backup one. The aim of the invention is to enhance the functionality of the control device providing the input control of both positive and negative voltages. In the case of control of a positive voltage, the control circuit contains a multi-detector 1, a key element 15, a non-inverting amplifier 18, a key element 19. The negative voltage channel is closed. Upon arrival at the control of negative voltage from the multiplexer 1, the positive voltage channel is closed by the signal from the output of the null organ 17 and the negative voltage channel is opened by the signal from the code of the logical inverter 22. The negative voltage channel includes the key element 16, the inverting amplifier 20 and key element 21. If the output voltage of any monitored channel exceeds the allowable value or becomes less than it, the control unit 6 outputs the signal and the display unit 14 highlights the number not spravno channel. 1 il. i With Od Sl 00 th

Description

The invention relates to electrical engineering and is intended to control multichannel systems of secondary power supply sources (IREs) j to determine the nature of the malfunction, the number of the faulty channel and the automatic disconnection from the network of the faulty channel or switch to the backup one.

The purpose of the invention is paciro-i-control functionality of the control device by providing control of both positive and negative voltages.

The drawing shows a functional scheme of a multichannel device for monitoring systems of secondary power supply sources.

The device contains a multiplexer 1, the information inputs of which are the inputs of the device and are connected to the outputs of controlled channels, the control inputs of which are connected to the output of counter 2, the input of which is connected to the output of generator 3, the outputs of the counter 2 are connected via decoder 4 to block 5 matching elements, another input of which is connected to the output of the generator 3, the control unit 6, consisting of the overvoltage sensor 7, the reduced voltage sensor 8, whose inputs are combined and are the input of the control unit b The outputs of which are connected to the inputs of the element OR 9, the outputs of which and the outputs of the sensors 7, 8 are control unit b and are connected to the information inputs of the memory unit 10 to the synchronous inputs of which the outputs of the matching elements 5 are connected.

The block is executed on registers 11–13, the number of which is determined by the number of monitored parameters, and the size by the number of monitored channels.

The information outputs of the memory unit 10 are connected to the display unit 14, the executive outputs of the memory unit are the device outputs and form the disconnecting signals of the faulty channel from the network.

The inputs of the key elements 15 and 16 are combined and connected to the output of multiplexer 1 and the input of the zero-body 17, the output of the key element 15 is connected to the input of the non-inverting amplifier 18, the output of which is connected to the input of the key element 19, the output

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the key element 16 is connected to the input of the inverting amplifier 20, the code of which is connected to the input of the key element 21, the outputs of the key elements 19, 21 are combined and connected to the input of the control unit 6, the output of the zero body 17 is connected to the control inputs of the key elements 15-19 and the input of the logical inverter 22, the output of which is connected, to the control inputs of the key elements 16, 21.

The device works as follows.

If the channels of the multichannel IVE system work normally, then O signals are present at the outputs of sensors 7 and 8, the same O is present at the inputs of the ICH element, and consequently, at its output, i.e. O - at all outputs of the control unit and at the inputs of the memory unit, and O when the clock pulses are received from the coincidence circuit does not change the state of the registers of the memory unit.

If the output voltage of any IHE channel exceeds the permissible value, then the same signal appears at the output of sensor 7 - at the input of the ISh 9 element and at its output, i.e. 1 appears at the information inputs of registers 11, 12 of memory block 10, in which this 1 is recorded by a sync pulse, received from a block of 5 matching elements, indication block 14 generates signals of the p-th channel and increased voltage, signal 1. at the executive output of the memory block, it is a signal that the faulty p-th channel of the IWE system is turned off or is switched to the backup channel.

If the output voltage of any of the monitored IHE channels has dropped below the permissible limit, O remains at sensor 7, 1 appears at sensor 8, and 1 also appears at the input and output of the OR circuit 9e, i.e. at the information inputs of registers 12 and 13 of memory block 10, into which they record, at the time of arrival of the clock from the block of 5 coincidence elements, the display unit 14 injects the Ness-right signal in the j-th channel and Undervoltage, signal 1 at the executive output the memory block is a signal for switching off the faulty j-th channel of the power supply voltage or switching it to the backup channel.

The above is a description for. positive voltage when the voltage is controlled along the circuit: multiplexer 1 - key element 15 - non-inverting amplifier 18 - key element 19 - input of control unit 6. The zero-body 17 outputs a signal with a level of 0 or 1 (it depends on its implementation) to turn on this particular channel, i.e. A positive voltage arrives at the input of the Conrol unit. The negative voltage channel (key element 16 — inverting amplifier 20 — key, element 21) is opened by signal 1 or O, coming from the output of logical inverter 22.

When a negative voltage is monitored from multiplexer 1 (this can be in the process of overtaking all channels at any time), the positive voltage channel is closed by the signal from the output of the ul-organ 17, the signal from the output of the logical inverter 22 opens the channel negative voltage, the negative voltage is supplied through the key element 16 to the inverting amplifier 20, from whose output through the key element 21 a positive voltage is already fed to the input of the control unit 6. The gain of amplifiers 18 and 20 is chosen such that it is equal to one over both paths.

Transients from switching do not interfere with the operation of the control system as a whole, since the recording of information in each code register is delayed by a half-period of the generator due to the presence of a block of coincidence elements, i.e. in half a period, it is easy to switch the communication channels from the multiplexer to the control unit and the monitoring itself.

Claims (1)

Invention Formula A device for controlling multichannel systems of secondary power sources, containing a binary counter with p-outputs for the number of controlled channels ha 2, the outputs of the binary counter are connected to the control inputs of the multiplexer and the decoder, a generator, a sub output five 0 five 0 five 0 five 0 five A binary block input to the input, a block of matching elements that includes matching elements by the number of outputs of the decoder, one input of a block of matching elements is connected to the output of the generator and is a common first input for all matching elements, and every other input of a block of matching elements is the second the input of the corresponding coincidence element and is connected to the corresponding output of the decoder, the voltage monitoring unit, which includes the high voltage sensor, the low voltage sensor, and nt OR, and the inputs of the supercharged voltage sensor and the undervoltage sensor are combined and used as the input of the voltage control unit, the output of the higher voltage sensor is used as the first output of the voltage control unit, and is also connected to the first input of the element OR, output which is used as the second output of the voltage control unit, and the second input of the OR element is connected to the output of the low voltage sensor, used as the third output of the voltage control unit , the first, second and third outputs of the voltage control unit are connected to the information inputs of the memory block, the synchronous inputs of the memory block are connected to the outputs of the corresponding match elements of the block of match elements, and the m information outputs of the memory block are connected to the corresponding inputs of the display unit, with mouth m information multiplexer inputs are designed to connect to the corresponding controlled channels, characterized in that, in order to extend the functionality by providing monitoring positive and negative voltages, a null organ, a logic inverter, four key elements, an inverting and non-inverting amplifiers are introduced, the multiplexer output is connected to the inputs of the first and second key elements and a zero-organ, the output of the first key element is through a non-inverting amplifier connected to the input of the third key element, the output of the second key element through inverter5 1406582 : the primary url is connected to the input of the fourth key elements - via a logged key element, an output inverter, with the outputs the zero-body is connected to the control of the third and fourth key elevators of the first and third key elements and connected to the inputs directly, and to the control unit of the voltage control equal to the second and fourth inputs