RU95435U1 - COMPLEX POWER SUPPLY OF ANTENNA POST OF ANTI-ROCKET COMPLEX - Google Patents

Abstract

 1. The power supply complex of the antenna post of the anti-aircraft missile complex, electrically connected through connectors to the base power supply, to the electricity consumers of the antenna post and to its control panel, containing microcontrollers, microcircuits, relays, an electric cooling fan, auxiliary secondary power sources, as well as other components low-current and power electronics, characterized in that it functionally includes a distributor, an inverter, a converter and a switching unit, and the distributor is supplied with hour meter, the input of the distributor is connected to a three-phase source of basic power, and the outputs through the first and second circuit breakers are connected in parallel to several basic block connectors and to an inverter, at the input of which an industrial noise filter is installed, the output of the filter is connected by one phase to the input of the first microcontroller and three phase connected to the input of a three-phase bridge rectifier, the output of the rectifier is connected to the input of the starting current limiter, the output of the starting current limiter through the capacitor is connected to the voltage boost source, which is part of the converter, and through the control circuit of the first current sensor, the output of the start current limiter is connected to the input of the three-phase IGBT bridge, the output of the latter is connected by three phases with three resistors in the feedback circuits, and also in series through a filter plug carrier frequency, through the control circuit of the voltage sensor and through the third circuit breaker is connected to the first output block connector, the resistors of the feedback circuits are closed to the corresponding

Description

The utility model relates to power supply complexes of mobile objects equipped with electronic equipment, namely, power supply complexes of mobile defense electronic systems with basic power supply from stationary electric networks or from diesel generators with standard general industrial parameters of generated electricity. The proposed technical solution, in particular, can be used to modernize the antenna post of the Pechora 2M anti-aircraft missile system.

A known power supply system (see patent for utility model RU No. 86361, publication date 08/27/2009) of a shipborne automated control system (CACS), comprising a central control device, which includes a central electronic computer (CEC) and a panel connected to the CEC control, as well as a central switchgear (CIA) and at least one peripheral device for communication with control objects, including at least two channels, each of which contains a calculator module, connected via a redundant interface line of a local area network with a digital computer, an onboard equipment power module (MPBA), the control inputs and information outputs of which are connected to the corresponding outputs and inputs of the calculator module, an MPBA secondary power supply (IVEP), the output of which is connected through the main power voltage contactor with the MPBA power bus, as well as the emergency power voltage contactor, the output of which is connected to the MPBA power bus, the control input is connected to the output of the control panel a signal from the emergency power-on signal, and the input through the isolation unit for emergency power supply circuits is connected to the emergency power supply input of the CIA, while the CIA contains a monitoring and control device, a central power supply system connected to the input of the main power supply of the CIA, as well as a computer system power switching unit, inputs the main and emergency power supply of which are connected respectively to the output of the central power supply and emergency power supply and the emergency power input of the CIA, and the outputs are connected to the power bus of the computer system, to which, through the circuit isolation unit the power supply of the computing system is connected to the power inputs of the computer and modules of computers of peripheral communication devices with control objects, characterized in that the CIA additionally introduces a switching unit for standby power supply, the main and emergency power inputs of which are connected respectively to the output of the central power supply and emergency power supply and the emergency power input of the CIA, and the corresponding outputs are connected to the input of the voltage converter of the documentation device, to the input of the standby power of the monitoring and control device and to the bus standby supply voltage, which is connected through the isolation block of standby supply voltage circuits to the standby power inputs of the control panel and peripheral communication devices with control objects; in addition, the control and switching device contains an emergency power supply voltage control unit connected to the emergency power supply input of the CIA, two units insulation resistance control, one of which is connected to the input of the main power supply of the CIA, and the other to the output of the central power supply system, and a control unit whose inputs are not isolation references and control signal outputs are connected to the corresponding inputs and outputs of insulation resistance control blocks, as well as a data acquisition and processing unit based on a controller connected to a computer via an interface line of the serial channel, while the outputs of the control unit on which fault signals are generated isolation, connected to the corresponding inputs of the data collection and processing unit, the input of which is connected to the output of the the voltage of the emergency power supply, and the input according to the operability signal of the main power supply is connected to the corresponding output of the central power supply system, which is also connected to the corresponding control inputs of the switching unit of the standby power supply voltage and the switching unit of the power supply of the computer system, the control inputs of which are activated by the emergency power supply signal, as well as the control the input of the switching unit of the power supply of the computing system by a signal to turn on the complex is connected to the corresponding outputs of the control panel, the input input of the switching unit of the power supply of the computing system by the signal for switching on the emergency power supply for emergency ejection is connected to the corresponding output of the data acquisition and processing unit, the outputs of which are connected to the corresponding indicators of the control panel by the signals of the insulation and power supply failure, and the output by the switching signal of the documentation device is connected to the corresponding control input switching unit standby voltage.

This analogue uses an onboard ship network of sufficient power with an alternating current frequency of 400 Hz as the base power. This feature of the analogue does not allow it to be used for powering mobile defense electronic complexes with basic power from sources with general industrial parameters of generated electricity and with the requirement to receive, along with others, a secondary power voltage of 400 Hz, which is used to power a number of functionally important elements of the complex ( for example, gyroscopic devices with brushless drives). In addition, the presence in the structure of the power supply system of a central electronic computer (CE) makes the entire system vulnerable to malfunctions and software failures, which reduces its reliability. For this reason, in modern systems and power supply systems, it is preferable to use a multiprocessor control and self-diagnosis circuit built on the basis of microcontrollers.

The utility model aims to improve the power supply system of mobile defense electronic complexes with basic power from stationary electric networks or from diesel generators with standard general industrial parameters of the electricity they generate. When using the utility model, the following technical results are achieved:

1. The efficiency of the power complex of the antenna post of the anti-aircraft missile system is increasing (hereinafter, the abbreviation CEP is used)

2. Provides electrical protection for all consumers connected to the CEC, electricity consumers from overloads and short circuits

3. Increases the reliability of CEP

4. Without the use of a computer, integrated diagnostics of the CEC elements and signaling of its condition and of the most important parameters (availability, emergency modes, currents and voltages at the output of AC and DC sources) with remote transmission of information via the RS-485 interface are provided.

These technical results are achieved by the fact that the CEC, electrically connected, through connectors with a base power source, to the electricity consumers of the antenna post and its control panel, containing microcontrollers, microcircuits, relays, an electric cooling fan, auxiliary secondary power sources, as well as other components low-current and power electronics has characteristic features that determine its novelty. These features are as follows: CEP functionally includes a distributor, an inverter, a converter and a switching unit, the distributor being equipped with a hour meter, the input of the distributor is connected to a three-phase base power supply, and the outputs through the first and second circuit breakers are connected in parallel to several basic block connectors and with an inverter, at the input of which an industrial noise filter is installed, the output of the filter is connected in one phase to the input of the first microcontroller and, in three phases, is connected inen with the input of a three-phase bridge rectifier, the output of the rectifier is connected to the input of the starting current limiter, the output of the starting current limiter through a capacitor is connected to the voltage boost source that is part of the converter, and through the control circuit of the first current sensor, the output of the starting current limiter is connected to the input of a three-phase IGBT bridge , the output of the latter is connected by three phases with three resistors in the feedback circuits, as well as sequentially, through the filter plug of the carrier frequency, through the control circuit of the sensor, e.g. and through the third circuit breaker is connected to the first output block connector, the resistors of the feedback circuits are closed to the corresponding inputs of the second microcontroller, the six control outputs of which are connected to the gates of the field transistors of the IGVT bridge through the control voltage amplifiers connected through the power supply circuits to the inverter bipolar service source, and five other outputs are connected to the inputs of the first microcontroller, two more inputs of which are connected respectively to the signal The outputs of the first current sensor and the input voltage sensor, the outputs of the first microcontroller are also connected via an amplifier to a signal lamp, are connected also to other self-diagnosis indicators and to the input of the signal conditioning controller via RS-485 protocol, the output of which, in turn, connected to an external RS-485 interface bus; the converter contains a voltage boost source, which is connected through a capacitor to the output of the current sensor by power, and is connected to a microcontroller by control and connected to the output of the start current limiter via a capacitor output, and one of the secondary windings of the power transformer, which is part of the voltage boost source, is loaded on the circuit rectification-stabilization, which is also connected to the third microcontroller by the control bus, forming a power supply with controlled and uncontrolled outputs, both indicated The output outputs are equipped with low-pass filters, the controlled output equipped with a power transistor module, a voltmeter and a second current sensor, the signal circuit of which is closed to the corresponding input of the third microcontroller, is connected through the fourth circuit breaker to the third output block connector and is connected through the fifth circuit breaker and through the ammeter with the third block connector for connecting the battery, the uncontrolled output is connected to a boost converter, which is connected to the control bus Lenia third microcontroller output boost converter coupled to a supply input of the buck converter, which is connected with the third control input of the microcontroller and the function of the internal power supply service; the switching unit contains elements that provide galvanic isolation and amplification of the antenna post commands, as well as elements by turning on the electric fan at the command of the second microcontroller and is connected to the antenna post through the fourth block connector.

The indicated essence of the utility model is obviously associated with the claimed technical results, since the proposed technical solution does not use electric machine components of frequency conversion, which have a relatively low efficiency and low reliability compared to electronic components, and the built-in diagnostics of the CEC elements and signaling about its state and the most important parameters with remote transmission of information via the RS-485 interface is provided by the use of microcontrollers.

Figure 1 shows a circuit diagram of the CEP with the designation of its functional blocks by positions.

CEP functionally includes a distributor (1), an inverter (2), a converter (3), a switching unit (4), and electrical display elements (5). The distributor (1) is equipped with an hour meter (6), the input of the distributor (1) is connected to a three-phase base power supply (not shown), and the outputs through the first (7) and second (8) circuit breakers are connected in parallel with several basic block connectors “network” 3ph. 220 V / 50 Hz "(9) and with an inverter (2), at the input of which an industrial interference filter (10) is installed, the output of the filter (10) is connected via a limiting resistor (11) in one phase to the input of the first microcontroller (12) and, in three phases, connected to the input of a three-phase bridge rectifier (13), the output of the rectifier (13) is connected to the input of the starting current limiter (14), the output of the starting current limiter (14) is connected through the capacitor (15) to the voltage source (16) included in the composition of the converter (3), and through the control circuit of the first current sensor (17) the output of the limiter the starting current (14) is connected to the input of the three-phase IGWT bridge (18), the output of the latter is connected by three phases with three resistors in the feedback circuits (19), as well as sequentially, through the filter plug of the carrier frequency (20), through the control voltage sensor circuit (21) and through a third circuit breaker (22) connected to the first block connector (23) "network 3ph. 220 V / 400 Hz ”, the feedback loop resistors (19) are closed to the corresponding inputs of the second microcontroller (24), the six control outputs of which are connected to the gates of the field transistors of the IGVT bridge (18) through the control voltage amplifiers (25) connected by power circuits with a bipolar service source included in the inverter (26), and five other control outputs are connected to the inputs of the first microcontroller (12), two more inputs of which are connected respectively to the signal outputs of the first current sensor (17) and the limiter resistor (11), the outputs of the first microcontroller (12) are also connected through an amplifier (27) to a signal lamp (not shown), are also connected to other electrical display elements (5) and to the input of the signal conditioning controller via RS- protocol 485 (28), the output of which, in turn, is connected to the external RS-485 interface bus. The converter (3) contains a voltage boost source (16) connected by power to the output of the first current sensor (17), by control to the third microcontroller (29) and connected to the output of the start current limiter (14) through its capacitor (15). One of the secondary windings (30) of the power transformer, which is part of the voltage source (16), is loaded on the rectification-stabilization circuit, which is also connected to the third microcontroller (29) by the control bus, forming a secondary power supply (31) with controlled and uncontrolled outputs, both of these outputs are equipped with low-pass filters, a controlled output equipped with a power transistor module (32), a voltmeter (33) and a second current sensor (34), whose signal circuit is closed to the corresponding input of the third microcon the troller (29), connected through the fourth circuit breaker (35) to the second output block connector (36) "network + 27 V" and through the fifth circuit breaker (37) and through the ammeter (38) connected to the third block connector (39) " +27 V “battery” for connecting the battery, the uncontrolled output is connected to a boost converter (40), which is connected by a control bus to the third microcontroller (29), the output of a boost converter (40) is connected to the power input of a step-down converter (41), which is connected by an input control with a third mi a crocontroller (29) and performs the function of a service internal power source; the switching unit (4) contains elements that provide galvanic isolation and amplification of the antenna post commands, as well as elements that control the inclusion of an electric fan (42) by the command “OVERHEAT” from the second microcontroller (24). The switching unit (4) is connected to the antenna post through the fourth block connector (43).

CEP operates as follows:

Through the distributor (1), the three-phase voltage from the base power source enters the industrial noise filter (10) of the inverter (2) and is rectified by a three-phase bridge rectifier (13). The rectified voltage is modulated by the IGBT bridge (18) according to the signals from the control voltage amplifiers (25), and the PWM control signals are generated by the second microcontroller (24) by the feedback voltage from the resistors (19). The output filter plug of the carrier frequency (20) suppresses the carrier frequency of 14.4 kHz of the output voltage, so that a three-phase harmonic voltage system of 220 V / 400 Hz takes place at the inverter output. These voltages are supplied through the control circuit of the voltage sensor (21) and through the circuit breaker (21) to the first block connector (23) "network 3ph. 220 V / 400 Hz ”from which power is supplied to the corresponding elements of the antenna post. In addition to generating PWM control signals for the IGBT bridge, the second microcontroller (24) controls:

- the temperature of the crystal of the IGBT bridge (18), forming a signal “OVERHEAT”, which controls the inclusion of an electric fan (43) when exceeding 120 ° C;

- the value of the insulation resistance of the phases of the output voltage immediately after the supply voltage;

- the presence of a signal from the control voltage amplifiers (25) about a short circuit in the IGWT bridge (18).

The first microcontroller (12) controls:

- the voltage of the basic power supply "~ 220 V 50 Hz", according to the signal from the limiting resistor (11)

- load current from the first current sensor (17).

The signaling about the state of the CEC and its parameters is transmitted to the control panel of the complex via the RS-485 interface through the controller (28) connected to the second microcontroller. The following fault signals from the first microcontroller (12) are received at the inputs of the second microcontroller:

- FAILURE And if the output voltage does not meet the required values,

- Short circuit And with a short circuit in the IGVT bridge,

- INSULATION with insulation resistance of the output phases less than 20 kOhm,

- OVERHEATING at a crystal temperature of the IGBT bridge over 120 ° C,

- a signal on the serial interface from the output of the converter,

- signals of the antenna post.

The first microcontroller (12) forms:

- clock signal of a serial communication interface with a converter (3),

- a command to prohibit the formation of PWM by the second microcontroller (23),

- team antenna post.

The ± 15 V power supply of the first current sensor (17) and the control voltage amplifiers of the IGWT bridge (18) is performed by rectifying the voltage of ~ 16 V 50 kHz. In the converter (3), the voltage supplement source (16) forms a voltage additive and increases the supply voltage of +310 V to +360 V. The second current sensor (34) gives a signal about the value of the load current. When the load current exceeds 150 A, the converter goes into current limiting mode, reducing the output voltage to 21 V, after which the output circuit opens upon command from the third microcontroller (29) to the power source (31). The step-up DC-converter (40) raises the voltage +27 V to +35 V, the step-down converter (41) generates secondary galvanically isolated voltages: ± 12 V, ~ 16 V 50 kHz and two stabilized voltages +5 V. These voltages are used for power supply of CEP elements.

The third microcontroller (29) controls:

- the presence of a signal from the amplifiers about a short circuit in the voltage source (16),

- presence of voltage

- load current from the second current sensor (34),

- output voltage +27 V,

- voltage +35 V boost converter (40)

The clock signal of the serial communication interface with the inverter (2) is input to the microcontroller input.

The microcontroller forms:

- PWM signals of source voltage boost control (16),

- control signal of the amplifier of the field-effect transistor module (32),

- signal through a serial interface to the inverter (2),

- PWM control signal boost converter (40),

- control signal of the buck converter (41),

fault signals:

- NON-SPD K when the output voltage does not match the required value,

- CURRENT K when exceeding the load current value of 150 A,

- Short circuit К at a short circuit in the source of voltage boost (16),

the switching unit (4) provides galvanic isolation and amplification of the antenna post commands using three amplifiers controlled by the first microcontroller (12), and also controls the inclusion of an electric fan (42) by the “OVERHEAT” command from the second microcontroller (24). Ammeter (38) shows the value of the charge current of the battery.

The hour meter (6) is powered by a voltage of ~ 220 V 50 Hz and shows the CEP operating time in operating mode. Display elements (5) display the current state of the CEP modes.

Claims (1)

1. The power supply complex of the antenna post of the anti-aircraft missile complex, electrically connected through connectors to the base power supply, to the electricity consumers of the antenna post and to its control panel, containing microcontrollers, microcircuits, relays, an electric cooling fan, auxiliary secondary power sources, as well as other components low-current and power electronics, characterized in that it functionally includes a distributor, an inverter, a converter and a switching unit, and the distributor is supplied with hour meter, the input of the distributor is connected to a three-phase source of basic power, and the outputs through the first and second circuit breakers are connected in parallel to several basic block connectors and to an inverter, at the input of which an industrial noise filter is installed, the output of the filter is connected by one phase to the input of the first microcontroller and three phase connected to the input of a three-phase bridge rectifier, the output of the rectifier is connected to the input of the starting current limiter, the output of the starting current limiter through the capacitor is connected to the voltage boost source, which is part of the converter, and through the control circuit of the first current sensor, the output of the start current limiter is connected to the input of the three-phase IGBT bridge, the output of the latter is connected by three phases with three resistors in the feedback circuits, and also in series through a filter plug carrier frequency, through the control circuit of the voltage sensor and through the third circuit breaker is connected to the first output block connector, the resistors of the feedback circuits are closed to the corresponding input odes of the second microcontroller, the six control outputs of which are connected to the gates of the field-effect transistors of the IGVT bridge through control voltage amplifiers connected through the power supply circuits to the bipolar service source included in the inverter, and five other outputs are connected to the inputs of the first microcontroller, the other two inputs of which are connected respectively with the signal outputs of the first current sensor and the input voltage sensor, the outputs of the first microcontroller are also connected through an amplifier with a signal lamp I, are also connected to other self-diagnosis indicators and to the input of the signal conditioning controller via RS-485 protocol, the output of which, in turn, is connected to the external RS-485 interface bus; the converter contains a voltage boost source, which is connected through the capacitor to the output of the current sensor by power, and is connected to the microcontroller by control and connected to the output of the start current limiter through the capacitor output, and one of the secondary windings of the power transformer, which is part of the voltage boost source, is loaded on rectification-stabilization circuit, which is also connected to the third microcontroller by the control bus, forming a power supply with controlled and uncontrolled outputs, both indicated The output outputs are equipped with low-pass filters, the controlled output equipped with a power transistor module, a voltmeter and a second current sensor, the signal circuit of which is closed to the corresponding input of the third microcontroller, is connected through the fourth circuit breaker to the third output block connector and is connected through the fifth circuit breaker and through the ammeter with the third block connector for connecting the battery, the uncontrolled output is connected to a boost converter, which is connected to the control bus Lenia third microcontroller output boost converter coupled to a supply input of the buck converter, which is connected with the third control input of the microcontroller; the switching unit contains elements that provide galvanic isolation and amplification of the antenna post commands, as well as elements by turning on the electric fan at the command of the second microcontroller and is connected to the antenna post through the fourth block connector.