RU2760729C1 - Automated test facility for ground-based experimental testing of spacecraft power supply systems - Google Patents

Abstract

FIELD: aerospace technology.

SUBSTANCE: automated test complex for ground-based experimental testing of spacecraft power supply systems refers to conversion technology and can be used for ground-based testing of spacecraft power supply systems that receive electricity from solar battery simulators and battery simulators. The task is solved by the fact that in an automated test complex for ground-based experimental testing of spacecraft power supply systems, connected to the tested unit of the spacecraft’s energy-converting equipment (ECE) and containing simulators of solar and electric batteries, as well as simulators of spacecraft load devices, an automated control system (ACS) and a Server in which all units of the complex are integrated into a single Ethernet information network, each of the solar and electric battery simulators and the load simulator is connected to a corresponding separate uninterruptible power supply (UPS) unit, each of which is connected to an industrial three-phase network, while all these UPS are connected to each other in parallel, and their outputs are synchronized, while the automated control system and the Server are also connected to the autonomous three-phase AC network formed by them.

EFFECT: increase in the fault tolerance and reliability of the automated test complex during ground-based experimental testing of spacecraft power supply systems due to the formation of an autonomous three-phase AC network.

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Description

The automated test complex for ground-based experimental testing of power supply systems for spacecraft refers to converter technology and can be used for ground testing of power supply systems for spacecraft, which receive electricity from simulators of solar batteries and from simulators of storage batteries. This system is an automated distributed energy conversion complex, which includes embedded digital computers, and which provides a fully automatic mode for testing power supply systems for spacecraft (SCS), which are characterized by increased reliability requirements. The system can be used for physical modeling of the SC SES at all stages of ground-based experimental development.

A device for testing secondary power supplies is known, presented in RF utility model No. 129263, and containing a primary power source, a test power supply system for a spacecraft, a recuperative-type load device unit simulating electrical loads of a spacecraft, and an uninterruptible power supply operating in dual mode. conversion of electricity.

The disadvantages of this device are: the need to use a special uninterruptible power supply that allows you to connect to it a regenerative-type load device, insufficient reliability of the device as a whole, due to the connection to the AC network through a common uninterruptible power supply; failure of which will inevitably lead to stoppage and disruption of tests. In addition, the disadvantage is the impossibility to fully test spacecraft power supply systems due to the absence of a solar battery simulator and a storage battery simulator, which narrows the functionality of the complex.

There is also known a complex for ground testing of power supply systems for spacecraft according to RF utility model No. 154432, containing an uninterruptible power supply, two recuperative load devices, a tested power supply system, a solar battery simulator and a battery simulator, in which the input terminals of the uninterruptible power supply are connected to an industrial AC mains, wherein the solar battery simulator and the storage battery simulator are connected to the respective terminals of the power supply system.

The disadvantage of the complex is also low reliability due to the connection to the AC network through a common uninterruptible power supply, failure of which will inevitably lead to stoppage and disruption of tests. In addition, the disadvantage of the complex is the lack of centralized control for carrying out fully automated tests and obtaining the information necessary for subsequent analysis, as well as for maintaining a test report.

The closest to the claimed utility model in terms of the achieved effect and the functions performed is an automated complex for ground control and testing of power supply systems for spacecraft according to utility model of the Russian Federation No. 90958, containing a control computer that performs the functions of a server that implements the management of the components of the complex by exchanging control and measuring information via the Ethernet interface, in addition, the complex includes solar battery simulators, battery simulation units, load simulation units, each of these units includes a controller connected to the control computer via an Ethernet interface, an Automated Control System (ACS) included as a part of the complex, provides checking of disconnected and connected circuits, as well as insulation resistance, telemetry of technological control commands, interrogation of temperature sensors and the state of the spacecraft power supply system. The server performs the logging and data collection during the tests. All blocks of the complex are united into a single Ethernet information network for the purpose of centralized control, carrying out fully automated tests and obtaining the information necessary for subsequent analysis, as well as for keeping a test report. The disadvantage is the inability to operate the complex in case of emergency shutdown of the industrial AC network.

The objective of the claimed invention is to increase the fault tolerance and reliability of the automated test complex during ground experimental testing of power supply systems for spacecraft by forming an autonomous three-phase AC network.

The problem is solved by the fact that in an automated test complex for ground-based experimental development of power supply systems for spacecraft, connected to the test unit of power-converting equipment (EPA) of the spacecraft, and containing simulators of solar and storage batteries, as well as simulators of loading devices of the spacecraft, an automated control system (ACK) and Server, while all the blocks of the complex are combined into a single information network Ethernet, each of the simulators of solar and storage batteries and the load is connected to the corresponding separate uninterruptible power supply (UPS), each of which is connected to an industrial three-phase network, while all These UPSs are connected in parallel with each other, and their outputs are synchronized, while the ASK and Server are also connected to the autonomous three-phase AC network formed by them.

The figure shows a block diagram of the proposed automated test complex for ground-based experimental testing of power supply systems for spacecraft.

This automated test complex allows conducting electrical ground tests of spacecraft power supply systems (SES SC) with an increased level of reliability. The complex can simulate the required number of elements of the SC SES, depending on the power and type of SES.

The figure shows simulated four lithium-ion batteries represented by battery simulators 1-4, and two solar panels simulated using two simulators 5 and 6. Simulation of the total equivalent onboard load is carried out using load simulator 7. Automated monitoring system ( ASK) 8, which is part of the complex, provides checking of disconnected and connected circuits, as well as insulation resistance, telemetry of technological control commands, polling of temperature sensors and state of the SC SES. The logging and data collection during the tests is carried out by Server 9, also connected to an autonomous power network of uninterruptible power supplies UPS 380 V, and, using a multiplex exchange channel (MCO), connected to the tested block of power conversion equipment (EPA) of the spacecraft 10. All blocks complexes are united into a single information network Ethernet, for the purpose of centralized control, carrying out fully automated tests and obtaining the information necessary for subsequent analysis, as well as for keeping a test report. The tested unit EPA KA 10 is connected to simulators of storage batteries 1-4, simulators of solar batteries 5 and 6 and load simulator 7. Each of the simulator units is connected to a corresponding separate UPS 11-17 connected in parallel with each other and with a primary source of electricity (industrial network AC 380 V).

Components of an automated test complex for ground-based experimental testing of power supply systems for spacecraft are implementations of known technical solutions. Their specific schematic and constructive-technological implementation is determined by the existing level of technology.

Simulators of storage batteries 1-4 are intended for: imitation of charging and discharging modes of storage batteries; simulating the voltage on each battery cell of the entire battery; imitation of pressure alarms; imitation of temperature sensors; imitation of analog pressure sensors; imitation of battery electric heaters. The simulator of the storage battery 8 provides the completeness of electrical checks of the automation of power supply systems, simulating various combinations of the state of the pressure and temperature sensors, various states of the voltage parameters of the storage battery and its elements with a minimum amount of time. The description of the specified simulator is given in the patent for utility model No. 73102.

Simulators of solar cells 5 and 6 reproduce on their output buses the static and dynamic characteristics of a solar battery, allow simulating the operation of solar cells of a satellite located in any type of working orbit, have the ability to simulate the modes "entering the shadow" and "leaving the shadow" (patents for utility model No. 50014, 52522).

The load simulation unit 7 allows simulating various types of loads: constant (active) load, impulse (or abrupt), complex (resistive-capacitive), frequency with a sinusoidal current (utility model patent No. 50317). When simulating a constant load, the simulator converts the DC power of the spacecraft power supply system into AC power with its subsequent transfer to the supply network. The complex load provides a synchronous parallel connection of a constant active resistance and a serial RC-circuit to the output bus of the spacecraft power supply system (SCS). Harmonic load is created by forming a sinusoidal current in the output buses of the KA's SES. In this case, the current changes in the frequency range from 20 Hz to 100 kHz with a continuously adjustable amplitude, which makes it possible to study the load capacity in several decades, as well as to measure the output impedance of the EPA unit. The impulse load provides an independent increase (surge) or decrease (shedding) of a constant load with an adjustable switching duration of connection or disconnection. The duration of the rise or drop of the load current depends on the parameters of the reference, the inductance of the supply wires and the magnitude of the surge or reset current.

ACK 8 is designed to monitor the status of relay contacts and electronic switches of the EPA unit; control of time and amplitude parameters of voltage pulses; generation of control commands in the form of voltage pulses or "dry" contact; formation of autonomous control commands with direct operator access to turning on and off the controlled object; imitation of resistive sensors and resistances; measurements of resistances, forward voltage drops across diodes and diode leakage currents at reverse voltage.

ACK provides control and exchange of information through a converter via the RS-485 interface 23 with ACK devices, exchange of information via Ethernet with Server 9.

During the operation of the complex, in the event of an emergency shutdown of the industrial AC network, all UPSs 11-17 are turned on, while the operation of the complex continues for a time depending on the power consumption and the capacity of the UPS batteries. If one (or more) of UPS 11-17 fails, the voltage in the 380 V autonomous network formed by the parallel connection of all UPSs will be supported by other UPSs, and the tests will continue. Thus, the proposed structure increases the reliability and increases the fault tolerance of the complex.

Claims (1)

An automated test complex for ground-based experimental testing of power supply systems for spacecraft, connected to the tested power-conversion equipment (EPA) unit of the spacecraft and containing simulators of solar and storage batteries, as well as simulators of spacecraft loading devices, an automated control system (ACS) and a Server, while all blocks of the complex are united into a single information network Ethernet, characterized in that each of the simulators of solar, storage batteries and loads is connected to a corresponding separate uninterruptible power supply (UPS), each of which is connected to an industrial three-phase network, while all of these UPSs are connected between themselves in parallel, and their outputs are synchronized, while the ASK and the Server are also connected to the autonomous three-phase AC network formed by them.

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