RU8179U1 - SYSTEM OF POWER SUPPLY OF THE COMPLEX OF SHIP RADIO ELECTRONIC EQUIPMENT - Google Patents

Abstract

The power supply system of the complex of shipboard electronic equipment, containing an input control device for network parameters, secondary power sources by the number of input channels of the complex, a central power management device and a block of managed switches, the first of which is connected to the power input of the central power management device, the output of the control signal for switching on the secondary power sources which is connected to the corresponding control inputs of managed switches, starting with the one whose outputs are channel-connected to the inputs of the secondary power supply channels of the complex, characterized in that it includes a standby power source and a guaranteed power unit connected by inputs to the main and backup three-phase AC networks, and the output to the standby power source, switched inputs three-phase current circuits of the unit of controlled switches and the input of the input control device for network parameters, the output of the network parameters of which is connected to the corresponding control input a block of controlled switches, and a voltage converter connected to the output of a controlled switch of the corresponding channel is added to each channel; a voltage circuit integrity control unit is connected to the outputs of the secondary power source and voltage converter, respectively, the first and second voltage switches, the control inputs of which are connected to the first relay output a signal generating unit, and a delay generating unit for the purpose of protection controlled by emergency alarm signals

Description

Power supply system for a complex of shipboard electronic equipment

The utility model relates to electrical engineering, namely, to systems for distributing power between the input channels of a complex of electronic equipment for automation and communication, mainly to systems with centralized control of the sequence of connecting input channels of the complex.

A known system of power distribution between electrical appliances 1.

The system contains a central control unit and several auxiliary units, each of which is equipped with a microprocessor programmable by the user. The inputs of the auxiliary units are connected to the mains, and the outputs are connected to the corresponding electrical appliances of the user. The system provides manual or automatic transmission of command signals and request signals from the central control unit to auxiliary units and transmission of signals corresponding to the state of the given electrical appliance from auxiliary units to the central unit. The system is equipped with a device for remote shutdown of the appliance, as well as a device for reviewing and checking a pre-programmed list of instructions.

A disadvantage of the known power supply system with centralized control of user channels is the lack of protection against emergency network failures and means of monitoring the health of load circuits.

H02J 13/00

A known power system 2 towed underwater complex containing a power supply vessel of the carrier vessel, comprising a rectifier connected to the alternating current main via a starting device, a converter with a charging current limiting unit, a current sensor and a protection against unipolar short circuits connected to the control input of the starting device as well as the power supply unit of the underwater vehicle and the power supply unit of the shunting device, consisting of two autonomous inverters with matching transformers for connecting to inputs of constant and pulse loads, starting converter and inverter control unit. The system includes means for protecting the power supply unit of the carrier vessel from short circuits and means for controlling the secondary power sides of the underwater vehicle and the shunting vehicle.

A disadvantage of the known system is the lack of centralized monitoring of the health of the circuits of the secondary power sources of the complex.

As a prototype of the proposed utility model, a multi-channel complex power supply system 3 was adopted, containing secondary power supplies connected to the inputs of the corresponding complex channels, control units providing a certain sequence of supply voltage to the inputs of the secondary power sources, a central power control device, the output of which is connected to control inputs of control units, and an input control device for the parameters of the supply network. The system provides distribution of the supply voltage of the primary AC network between the channels, secondary voltage conversion with specified output parameters, centralized control of the sequence of power supply to the devices of the complex and input control of the network parameters.

The disadvantage of the prototype system is the lack of means of protecting the power supply system from unacceptable changes or power outages, and means of protecting secondary power supply circuits. In addition, the system does not provide centralized monitoring of the health of the complex's power channels.

The objective of the utility model is to provide highly reliable distribution of power between the input channels of the complex of shipboard electronic equipment.

To solve this problem, the power supply system of the shipboard complex of electronic equipment, containing an input control device for network parameters, secondary power sources by the number of input channels of the complex, a central power management device and a block of managed switches, the first of which is connected to the power input of the central power management device, the output of the control signal for switching on the secondary power sources of which is connected to the corresponding control inputs controlled switches, starting from the second, the outputs of which are channel-connected to the inputs of the secondary power sources of the complex channels, an additional standby power supply and a guaranteed power supply unit connected to the main and standby three-phase AC networks, and an output to the standby power supply, and switched inputs are added three-phase current circuits of the unit of controlled switches and the input of the input control device of the network parameters, the signal output of the normal network parameters of which is connected to corresponding to the control input of the managed switches block, and a voltage converter connected to the output of the controlled switch of the corresponding channel with a phase circuit integrity control unit connected to the outputs of the secondary power source and voltage converter, respectively, the first and second voltage switches, the control inputs of which are connected to the first output of the relay block for signal generation, and the delay generation unit with a protection circuit, we control alarm signal of the voltage converter and the secondary power source, the control input of which is connected to the first output of the delay generating unit, and the output is connected to the inputs of the insulation resistance control unit and the relay signal generating unit, the information output and the control input of the relay signal generating unit of each channel are connected respectively to the input of the channel health signal and

the output of the power-on signal of the channel of the central power management device, the information inputs of which are connected to the output signal of a malfunction of the input network of the input control device of the network parameters and the outputs of the insulation resistance control units of each channel, and the output of the control signal to turn on the secondary power sources is also connected to the control inputs of all the generating units delays, the second output of each of which is connected to the corresponding control input of the control delay delay signal yaemogo switch outputs standby power supply connected to the inputs of a DC power supply of the central control unit, managed switches block, blocks forming delay and monitoring the insulation resistance of each channel and to a circuit block contact emergency shutdown system guaranteed power supply unit.

The essence of the utility model is illustrated by drawings, on which:

FIG. 1 is a block diagram of a complex power supply system;

FIG. 2 is a diagram of a secondary DC power source;

FIG. 3 is a diagram of an input control device for network parameters;

FIG. 4 is a block diagram of a managed switch;

FIG. 5 is a diagram of a delay generating unit;

FIG. 6 is a block diagram of a control block for resisting insulation.

According to FIG. 1 power supply system of the complex contains a guaranteed power unit 1, the output of which is connected to a standby DC power supply 2, a device 3 for input control of the network parameters and a block 4 of controlled switches for three-phase current circuits. The output of the first managed switch 5 (Km 5) of block 4 is connected to the power input of the three-phase current of the central power management device 6, and the outputs of each of the following managed switches Km 7, ..., Km TN, starting from the second switch Km 7i of block 4, are connected in each channel to the input of the secondary source 8 of the pigmentation of direct current (VIL) and the input of the Converter 9 voltage of three-phase current (PN) with a unit for monitoring the integrity of phase circuits. The outputs of the VIL 8 and PN 9 are connected to the inputs of the switches 10 and 11 of the DC and AC three-phase current voltages, respectively. The control input of the VIL 8 is connected to the first output of the remote control signal (remote control of the VIL) of the delay generating unit 12, the first control input of which (phase loss signal - PF) is connected to the output of the integrity control unit of the phase circuits PN 9, and the second control input (emergency faults of the secondary power source (AVIP) - to the output of the AVP VIL 8. The output of the VIL 8 is connected to the first inputs of the insulation resistance control unit 13 and the relay signal generating unit 14, the first output of which is connected to the control inputs of the switch s 10 and 11 voltage. The information output and control input of block 14 are connected to the input of the health signal of the corresponding channel (Fix channel 1, ..., Repair channel N) and the output of the power-on signal of the corresponding channel of the complex (On channel 1, .. ., Including the power supply channel N) of the central power management device 6, the input of the insulation signal of the DC circuit isolation (Np. SI 1, ..., Np. SI N) of which is connected to the output of the insulation resistance monitoring unit 13 of the corresponding channel. The first information input of the Central power management device 6 is connected to the output signal of a fault signal of the input network (Np. Input network) of the device 3 input control network parameters. The signal output of the normal parameters of the input network (Norm. PS) of device 3 is connected to the first control inputs of the managed switches Km 5, Km 7i, ..., Km TN block 4. The second control inputs

managed switches Km 7i, ..., Km TN are connected to the output of the secondary power source enable signal (On VIP) of the central power management device 6, which is also connected to the control inputs of the channel delay generation units 12 from the first to the Nth, second outputs - delay signals on the channels (Zd. on. 1, ..., Zd. on. N) - which are connected to the third control inputs of the switches Km 7i, ..., Km TN, respectively. The outputs of the standby power supply 2 are connected to the DC power inputs of the central power management device 6, unit 4 of the managed switches, as well as delay generating units 12 and channel isolation resistance monitoring units 13 from the 1st to the Nth.

The guaranteed power unit 1 comprises an uninterruptible power supply device 15 that controls the connection of a three-phase starter 16 to a main or standby network of a three-phase current of industrial frequency (220 V, 50 Hz). The outputs of the starter 16 are connected to an electric machine frequency converter 17, the control input of which is connected to the output of the voltage regulation unit 18, which is connected to the output of the uninterruptible power supply device 15. The rotor of the machine frequency converter 17 is mechanically connected to the power supply emergency shutdown block 19, which is connected to the output circuit (-27 V dezh.) Of the standby power source 2. From the output of the frequency converter 17, three-phase AC voltage 3 220V, 400 Hz is supplied to the inputs of the power supply system.

The standby DC power supply 2 (27 V, 5 A dezh) and the secondary DC power sources 8 (27 V, 40 A) of the system channels are made according to a similar circuit shown in FIG. 2. The power supply 2 (8) contains an input mains rectifier 20 (diode assembly), a radio-frequency filter (not shown for simplicity), a current limiter 21 with a shunt thyristor and its control circuit, a capacitive smoothing filter 22, a refueling inverter 23 made along the bridge a circuit (in source 2, in half-bridge) on power transistors, a power transformer 24, an output rectifier 25 with a smoothing filter, and an inverter control unit 26, including a driver and a pulse-width modulator with a protection and logic command unit. In sources 8, a remote control unit and an AVIP emergency fault conditioner are additionally included in the modulator circuit.

The device 3 of the input control parameters of the network (Fig. 3) contains a power source 27, meters 28 and 29 of the effective voltage value (Oeff), the first connected to the phases Ф1 and Ф2, and the second to the phases Ф2 and ФЗ of the input network 3 220 V, 400 Hz, unit 30 for monitoring the integrity of phase circuits, unit 31 for frequency control, unit 32 for monitoring the lack of communication of AC circuits with the device body and block 33 of logic elements.

The power source 27 contains a rectifier 34, the input of which is connected to the three-phase current circuits through resistor-capacitive circuits. The rectifier output is filtered by a capacitive filter 35 and voltage stabilized by zener diodes 36-38.

Uaff meter 28 (29) contains a series-connected input voltage rectifier 39, a block 40 of correcting diode-resistor chains, a capacitive filter 41, and a block 42 of two threshold elements, one of which controls a decrease in voltage of 220 V, 400 Hz below an acceptable level, and the second is an increase in voltage above an acceptable level. The output signals of the corresponding threshold elements of block 42 are supplied as control signals LESS (M) and MORE (B) to the inputs of block 33 of logic elements.

The phase circuit integrity control unit 30 contains a variable component detector 43 at the output of the rectifier 34 of the power supply 27, a capacitive storage 44, and a transistor amplifier 45. The output of the unit 30 is connected to the input of the phase loss (PF) control signal of the logic unit 33.

The frequency control unit 31 includes a transistor amplifier 46, a differentiating circuit 47, an active filter 48, an operational amplifier 49, a comparator 50, and zener diodes 37 and 38 of a power supply 27 as a reference voltage source. From the output of the comparator to the input of the block 33 of the logic elements receives the control signal f of the frequency deviation from the nominal value.

The unit 32 for monitoring the lack of connection of AC circuits with the device case contains a resistor divider 51 between the zero point of the capacitive divider at the input of the power supply 27 and the device body, a rectifier 52 with a capacitive filter at the output, a comparator 53 and a zener diode 38 of the power supply 27 . At the output of block 32, a control signal of phase closure to the housing (FC) is generated, which is input to the block of logic elements 33.

The central power management device 6 is implemented on the basis of a microprocessor. Provides processing of input signals Np. in. Networks, Np. SI, Corr. can and control signals On VIL, incl. Pete. can .. Power Inputs

devices 6 are connected to the standby power source 2 and the output of Km 5 block 4 managed switches.

Block 4 of controlled switches (see Fig. 4) of three-phase current circuits provides the supply voltage of three-phase current to the central power control device 6 and serial connection of secondary power sources 8 and channel voltage converters 9 of the channels from the first to the Nth complex to the three-phase current circuits. The first managed switch Km 5 of block 4 contains a relay 54 with normally open contacts 54k and a contactor 55 of three-phase circuits. Terminal A of the relay coil 54 is connected to the first control input (Norm. PS) of block 4, and the terminals B of the relay coil 54 and contactor 55 are connected to the negative bus (-27 V dezh) of the standby power supply 2, positive bus (+27 V dezh) which, through terminal 54k of relay 54, is connected to terminal A of the coil of contactor 55. Controlled 11 channel switches Km 7i, ..., Km 7n are made in the same way. Each of them contains a relay 56 connected by a terminal A of the winding to the input of the control signal Norm. PS unit 4, and output B to the bus (-27 V dezh), and an additional relay 57, the winding of which is connected to the second (On VIP) and third (Rear On) control inputs Km 7, ..., Km 7m. A normally open contact 57k of relay 57 is connected in series with contact 56k of relay 56 in the connection circuit of the coil of contactor 58 to the buses of the standby power supply 2. An output circuit (-27 V dej.) Of the power supply 2 is connected as shown in FIG. 4, the contact block 19 of an emergency shutdown of the power supply system, mechanically connected with the rotor of the electric machine converter 17 of the frequency of the guaranteed power unit 1.

Converter 9 voltage input voltage 3 220 V, 400 Hz to voltage 3 36 V, 400 Hz contains transformers, a rectifier with a capacitive filter. The phase circuit integrity control unit PN 9 contains a parametric stabilizer, capacitors and a transistor amplifier loaded on a relay 59, normally closed contacts 59k of which are included in the protection circuit of the delay generation unit 12.

The delay generating unit 12 is made according to the circuit shown in FIG. 5. Block 12 contains relays 60 and 61 with normally closed contacts bOK and 61, three relays

62, 63, and 64 with normally open contacts 62k1, 62k2, 63 and 64, a resistor 65 and a capacitor 66 connected in series, and a resistor 67 and a capacitor 68 connected in series, to the plates of which a relay coil 63 is connected in parallel. A common connection point of the resistor 65 with a capacitor 66 is connected to terminal A of the relay coil 61, terminal B of which is connected via a jumper 69 to the second capacitor plate 66 and is connected via terminal BOK of relay 60 to terminal B of relay coil 60, terminal A of which is connected to control input On. VIL of unit 12. A common point of resistors 65 and 67, terminal A of relay coil 64, as well as through series-connected terminal 6 of IK, and a protection circuit including a normally closed contact of the OF relay 59 are connected to the positive bus (+27 V dezh) of the power supply 2 the phase circuit integrity control unit GSh 9 and the VIL 8 emergency fault AVIP contact, terminal A of relay relay 62 is connected. Terminal B of relay windings 60 and 62 is connected to the negative bus (-27 V dezh) of power supply 2, and terminal B is connected through terminal 62k2 relay windings 62 and through contact bZk terminal B of the relay winding 64, and besides it KfftOpQiJ

th, the contact circuit 62k1 relay 62, the output is connected to the signal output rear. incl. block 12 forming a delay. Contact 64k of relay 64 is included in the signal conditioning circuit

DU VIL; remote control of VIL 8 inclusion.

Block 13 monitoring the insulation resistance of DC circuits is made according to the circuit shown in Fig.6. Block 13 contains an insulation resistance meter 70 with a threshold switch at the output, a tunable pulse generator 71 connected to the output of the standby power supply 2, and a block 72 of logic elements controlling the relays 73 - 80 of meter 70. The meter 70 contains shunt resistors 81 and 82, the common the point of which is connected to the body of the device. The second output of the resistor 81 through pin 73 is connected to the VIL 8 bus (+27 V), and the second output of the resistor 82 through contact 74 to the bus (-27 V) of VIL 8. In parallel to the resistor 81, the capacitor plates 83 are connected through contacts 75 k and 76 and through the contacts 78k and 79 to the capacitor 84. The capacitors 85 and 86 are connected in parallel to the resistor 82 through pairs of contacts 76k and 77k. 79k and 80, respectively. The potential plates of the capacitors 84 and 86 are connected to the inputs of the operational amplifiers 87 and 88, respectively, to the outputs of which an adder 89 on the operational amplifier is connected. The output of the adder 89 is connected to the input of the voltage comparator 90, the second input of which is connected to the resistor 91 of the voltage reference driver. Relay 92 is connected to the output of comparator 90, normally open contacts 92k of which are connected to the output signal circuit Нп. SI block 13 insulation resistance control.

The power supply system of the complex shipboard electronic equipment operates as follows.

When connected to the power panel, the uninterruptible power supply unit 15 of the guaranteed power unit 1 supplies the voltage of the main network of three-phase current 220 V 50 Hz through the contactors of the three-phase starter 16 to the inputs of the machine frequency converter 17 and automatic switching of the starter 16 to the input of the backup network when the mains voltage fails. The generator of the frequency converter 17 generates an output voltage of 3 220 V, 400 Hz, supplied to the inputs of the standby power supply 2, devices 3 of the input control network parameters and the inputs of the unit 4 of the controlled switches of the three-phase current circuits of the power supply system.

In the standby power supply 2 (see Fig. 2), the input voltage is rectified by the diode assembly 20, filtered by an RF filter and smoothed by a filter 22. A current limiter 21 limits the starting currents due to the charge of the smoothing filter capacitors. The rectified voltage is converted by the inverter 23 into an alternating voltage of a rectangular shape with a pause at zero and a frequency of 25-30 kHz. The power transformer assembly 24 lowers the output voltage of the inverter 23 to the required level. The reduced high-frequency voltage is rectified by a rectifier 25 with a smoothing filter. The power transistors of the inverter 23 are controlled by the output signals of the inverter control unit 26. The duration of the control pulses is set by a pulse-width modulator

block 26, which provides a change in their duration when exposed to disturbing factors in order to keep the output voltage of the power supply 2 unchanged.

The output voltage (27 V, 5A) of the standby power source 2 is supplied to the DC power inputs of the central power management device 6, managed switches Km 5, Km 7, ..., Km 7, blocks 12 and 13 of channels 1 through

Nth complex.

Input control network parameters 3 220 V, 400 Hz as follows. The input voltage of the three-phase current (see Fig. 3) is fed through resistor-capacitive circuits to the input of the rectifier 34 of the power supply 27, the output voltage of which is filtered by the capacitive filter 35, stabilized by the voltage by the zener diodes 36 - 38 and supplied to the measuring units 30 - 32 and to the power inputs block 33 of the logical elements of the device 3.

Meters 28 and 29 of the effective voltage value are connected directly to the phases F1 - Ф2 and Ф2 - ФЗ, respectively, of the input circuits. The input voltage of the meter 28 (29) is rectified by a rectifier 39, stabilized by a diode-resistor circuit 40, and supplied to the transistor amplifiers of a block of threshold elements 42 loaded with optoelectronic switches. One threshold element of block 42 controls a decrease in voltage of 220 V, 400 Hz below an acceptable level, and the other controls an increase in voltage above an acceptable level. If the measured voltage is less than or greater than the threshold element settings of block 42, then the optoelectronic switches insert the corresponding signal M or B at the inputs of the logic unit 33 of device 3. At the rated voltage value, there are no signals at the output of the threshold element block 42.

Unit 30 monitoring the integrity of the phase circuits detects the variable component of the voltage at the output of the rectifier 34 of the power supply 27. In the presence of all phases of the voltage 220 V, 400 Hz at the output of the rectifier 34 there are no voltage ripples, and the transistor amplifier 45 is open through a resistor connected to the zener diode 37 of the power supply 27. If any of the phases breaks at the output

of the rectifier 34, an alternating component appears, the negative half-wave of which passes through the capacitor of the identifier 43 of the alternating component, is rectified, then filtered by a capacitive filter 44, the negative voltage from which closes the transistor amplifier 45. The absence of the output current of the amplifier 45 serves as an OF signal at the input of the block of logic elements 33.

In block 31, the frequency control compares the voltage at the output of the active filter 48, supplied after amplification by the operational amplifier 49 to the first input of the voltage comparator 50, with the reference voltage taken from the zener diode 38 of the power supply 27. At a voltage frequency of 220 V below the setpoint, the comparator 50 is activated and generates a signal f to the input of block 33.

The presence of communication of any of the phase circuits with the housing of the device is controlled by block 32 by measuring the AC voltage occurring between the sixtile point of the input capacitive divider of the power source 27 and the housing of the device. This voltage is removed from the resistor divider 51 of block 32, rectified by a rectifier 52, filtered and fed to the input of the voltage comparator 53, where it is compared with the reference voltage of the zener diode 38 of the power supply 27. At a certain value of the insulation resistance of the phase circuits, the measured voltage exceeds the reference voltage, which leads to the operation of the comparator 53 and the appearance of the FC control signal block 33 at its output and input.

Block 33 of the logic elements in the absence of control signals generates an output signal Norm. PS, and if at the input of at least one of the control signals produces a signal Np. in. network. In this case, on the front panel of the device 3, the indicators of the corresponding signals M, B, OF, FC and f network parameters that do not correspond to the required values are illuminated. The indicator control circuits in FIG. 3 are not given for simplicity.

From the output of the device 3 input control parameters of the network signal Norm. The PS is fed to the first control inputs of the managed switches Km 5, Km 7i, ..., Km 7n of block 4 (see Fig. 4). The appearance of the control voltage at terminal A of the coil of the relay 54 Km 5 leads to the operation of the relay 54 and the closure of the contact 54k in the connection circuit of the coil of the contactor 55 to the standby power supply 2. Contacts 55k of switched three-phase current circuits are closed, providing a supply voltage of three-phase current from the output of Km 5 to the central power control device 6, which turns on and generates a signal On. VIL, which controls the alternate connection of managed switches Km 7i, ..., Km 7ts to the inputs of secondary sources 8 and voltage converters 9 of the complex’s channels from the first to the Nth. If there are control signals at the inputs of the switches Km 7i, ..., Km TN Norm. PS and On VIP contacts 56k of relay 56 are closed, and relay 57 of all channels are prepared for operation. At the same time, the On signal is applied to block 4 of the switches. VIP arrives at the control inputs of the blocks 12 forming the delay of channels from the first to the Nth.

Consider the operation of block 12 of one channel (see Fig. 5). In the absence of a control signal at the input of block 12, the capacitor 66 is charged through the circuit from (+27 V dezh.) Through a resistor 65, relay coil 61 and normally closed contacts 60 of relay 60 to (-27 V dezh.). In this case, the normally closed contacts 6IK of the relay 61 are open. When a control signal is received, On VIP relay 60 is activated, opening the contacts side. The capacitor 66 begins to discharge through the coil of the relay 61 and jumper 69. At the end of the discharge of the capacitor 66, the relay 61 is de-energized, closing the contacts 6IK, which leads to the operation of the relay 62 and the closure of the contacts 62k1 of the control signal circuit On. ass G, which goes to the third controlled input of the switch Km 7. When a signal is received, rear. incl. G relay 57 Km switch is activated,

contacts 57k are closed, which, in turn, leads to the closure of contacts 58k of the contactor 58 of the three-phase current circuits Km 7i. The secondary power source 8 and the voltage converter 9 receives a supply voltage of 3 220 V, 400 Hz. At the same time, the contacts 62k2 of the relay 62 of the delay forming unit 12 are closed. Capacitor 68 begins to charge on the circuit: (+27 V dezh.), Resistor 67, contacts 62k2, (-27 V dezh.). At the end of the charge of the capacitor 68, relays 63 and 64 are sequentially activated, closing the contacts 64k in the control signal circuit of the VIP VIP, which is fed to

the modulator of the VIL 8 inverter control unit 26. The voltage from the output of the VIL 8 is supplied to the input of the voltage switch 10 and the input of the relay unit for generating signals, which broadcasts the signal can 1 to the input of the central power management device 6. The device 6 generates a control signal On. Pete. can 1, which is fed to the control input of the relay block 14 of the formation of signals. From the output of block 14, a signal is supplied to the control inputs of the voltage switches 10 and 11, providing a voltage of 27 V, 40 A, and 3 36 V, 400 Hz to the inputs of the first channel of the complex. Next, the channels from the second to the Nth complex are connected in series with a delay of the relative first channel, determined by the choice of the parameters of the charging circuit of the capacitors 66 of the delay forming unit 12 of the corresponding channel.

In the main mode of the power supply system of the complex, continuous monitoring of the parameters of the input AC network and the health of the circuits of the secondary voltage converters are carried out.

In the event of an unexpected disconnection of the guaranteed power supply unit 1 from the power switchboard and the supply of mains voltage to the electrical machine frequency converter 17, the contact block 19 of the emergency shutdown of the power supply system, mechanically connected with the rotor of the converter 17, disconnects the output circuit (-27 V) of the standby power supply 2 . In this case, the contactor windings are 55 Km 5 and 58 Km 7i, ...,

Km 7k of the block 4 of the managed switches are de-energized, the contacts 55k and 58k are opened, and the three-phase current supply voltage is removed from the central power management device 6 and the inputs of the VIP 8 and PN 9 channels of the complex from the first to the Nth.

When the output of the block 33 of the logical elements of the device 3 input control parameters of the network signal Np. in. network signal Norm. The PS is removed from the block of 4 managed switches. Relays 54 Km 5 and relays 56 Km 7i, ..., Km 7 are de-energized, opening the power supply circuits of the windings of the contactors 55 and 58, and the contacts 55k, 58k of the three-phase circuits open. At the same time, the Np signal also enters the central device 6. in. network, and on the front panel of device 3 the indicator of the corresponding control signal M, B, OF, f, or FC of the network parameter that does not satisfy the required values lights up.

If a wrong connection or lack of integrity of the phase circuits of the voltage converter 9 of one of the channels is detected, the relay 59 of the integrity control unit of the PN 9 phase chains is activated. incl. unit 12, which leads to de-energization of the coil of the relay 57 of the managed switch, opening the power circuit of the winding of the contactor 58 and opening the three-phase connection circuit of the corresponding channel. Similarly, in the event of an emergency malfunction of the secondary power supply 8 by the AVIP signal from the output of the VIL 8 inverter control unit 26, the AVIP contacts in the power supply circuit of relay winding 62 of unit 12 open. Contacts 62k1 of the relay open, and the signal incl. removed from the output of block 12.

The operation of the insulation resistance meter 70 of the insulation resistance monitoring unit 13 (see FIG. 6) is based on the method of three voltmeter readings. Each measurement cycle consists of three clock cycles, the duration of which and the measurement cycle as a whole are set by the tunable pulse generator 71. At the first cycle, the contacts 73k, 75k and 76k of the relay 73, 75, 76 are closed, controlled by the block of logic elements 72, connecting the voltage (+ 27V) from the output of the VIL 8 through the reference resistor 81 to the device body and the capacitor 83. A potential appears on the capacitor 83 corresponding to the steady-state voltage value (+27 V) relative to the instrument case. At the next step, contacts 73k and 75k open and close contacts 74k and 77k. A potential appears on the capacitor 85, corresponding to the steady-state voltage value between the (-27 V) VIL 8 and the housing. On the third step, contacts 74k, 76k and 77k open and contacts 78k, 79ic and 80ic are closed. The potentials are overwritten from the capacitors 83, 85 to the capacitors 84, 86. The voltage from the capacitors 84, 86 through the operational amplifiers 87 and 88, turned on in the repeater mode, is fed to the adder 89, where these voltages are added by the absolute value, and then fed to one of the inputs kompfator 90 voltage. The second input of the comparator 90 is supplied with a reference voltage (part of the controlled voltage of 27 V). If the equivalent insulation resistance is less than the specified value, the voltage of the adder 89 is greater than the reference voltage, the comparator 90 generates a signal Np. SI on the relay 92, and a signal is transmitted from the output of block 13 of the corresponding channel. SI in the Central power management device 6. At the same time, a malfunction indicator lights up on the front panel of unit 13.

The proposed structure of the power supply system also allows for the introduction of additional switching links to carry out centralized control of the actuation of various actuators of the complex. When applying a supply voltage to the switch of the controlled mechanism, the ready-to-turn on signal of the mechanism is relayed by the relay unit 14 for generating signals to the central power control device 6. The latter contains appropriate control signals at specified intervals in the presence of a signal of readiness of the mechanism and in the absence of information signals Np. in. Networks, Np. SI 1, ..., Np. SI N. When deviations from the specified operating mode appear, the formation of control signals stops, and the signal is not supplied to the control input of the corresponding switch, which does not allow actuating the actuator until the fault is eliminated.

Thus, the proposed power supply system for the complex of shipboard electronic equipment provides the conversion of the three-phase current voltage into direct and alternating current voltage with the parameters necessary for powering the complex devices, centralized power distribution between the complex channels, remote control of the complex channel connection with a given sequence, health monitoring and high degree of protection of AC and DC circuits against overloads, short circuits Kicks and overvoltages, which increases reliability and improves system performance.

and the accompanying drawings when using well-known components and technological equipment and used for its intended purpose for centralized distribution of power between the channels of the complex of electronic equipment.

LIST OF REFERENCES

1. Application EPO No. 69470, IPC H02J 13/00, publication 01/12/83

2. RF patent No. 2004051, IPC H02J 7/34, publication November 30, 1993.

Z.Zh.A. Mkrtchyan. Power supply of electronic computers.- M.Energy.-1980.- S. 133-136, prototype.

The list of captions to FIG. 1

1- guaranteed power unit,

2 - standby DC power supply,

3- device input control network parameters

4- block managed switches,

5 - the first managed switch,

6- central power management device, 71, ..., 7ff - managed switches,

8- secondary power supply,

9 - voltage converter, 10, 11 - voltage switches,

12 - delay generation unit,

13- insulation resistance control unit,

14-relay signal conditioning unit,

15 - uninterruptible power supply,

16-phase starter

17-machine frequency converter,

18- voltage regulation unit,

19- block contact system emergency shutdown

Power supply system ... to the List of captions to FIG. 3 27- power supply, 28 and 29 — voltage effective value meters, 30 — phase circuit integrity control unit, 31 — frequency control unit, 32 — control unit for the absence of connection of AC circuits with the device ohm. 33- block 33 logic elements, 34- rectifier, 35- capacitive filter 36, ..., 38- zener diodes, 39- input voltage rectifier, 40- block of correcting diode-resistor circuits, 41- capacitive filter, 42- block of two threshold elements, 43- identifier of a variable component, 44- capacitive storage, 45, 46 - transistor amplifiers, 47- differentiating circuit, 48- active filter, 49- operational amplifier, 50- comparator, 51-resistor divider, 52- rectifier, 53 - comparator. ((: & i6i Power System ...

Claims (1)

The power supply system of the ship’s electronic equipment complex, which contains an input control device for network parameters, secondary power sources by the number of input channels of the complex, a central power management device and a block of managed switches, the first of which is connected to the power input of the central power management device, and the output of the secondary turn-on control signal power sources which is connected to the corresponding control inputs of managed switches, starting with the one whose outputs are channel-connected to the inputs of the secondary power sources of the complex channels, characterized in that it includes a standby power source and a guaranteed power unit connected by inputs to the main and backup three-phase AC networks, and the output to the standby power source, switched inputs three-phase current circuits of the unit of controlled switches and the input of the input control device for network parameters, the output of the network parameters of which is connected to the corresponding control input a block of controlled switches, and a voltage converter connected to the output of a controlled switch of the corresponding channel is added to each channel; a voltage circuit integrity control unit is connected to the outputs of the secondary power source and voltage converter, respectively, the first and second voltage switches, the control inputs of which are connected to the first relay output a signal generating unit, and a delay generating unit for the purpose of protection controlled by emergency alarm signals and a voltage converter and a secondary power source, the control input of which is connected to the first output of the delay generating unit, and the output is connected to the inputs of the insulation resistance control unit and the relay signal generating unit, the information output and the control input of the relay signal generating unit of each channel are connected respectively to the signal input the health of the channel and the output of the power-on signal of the channel of the central power management device, the information inputs of which are connected to the output signal of a malfunction of the input network of the input control device of the network parameters and the outputs of the insulation resistance control unit of each channel, and the output of the control signal for turning on the secondary power sources is also connected to the control inputs of all delay generating units, the second output of each of which is connected to the corresponding control input of the turn-on delay signal managed switch, the outputs of the standby power source are connected to the DC power inputs of the central control device power supply, a block of controlled switches, a delay generation block and an insulation resistance control of each channel and to the emergency contact block circuit of the power supply system of the guaranteed power unit.