RU2634473C2 - Method of controlling independent power supply system of spacecraft - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: method of controlling an independent power supply system comprising a solar battery and n storage batteries, a voltage regulator connected between the solar batteries and the load and n charging and n discharging devices consists in controlling the voltage regulator and the charge-discharge devices depending on the input and the output system voltage, controlling the charging and discharging degree of the storage batteries, prohibiting the work of the respective charging device when the maximum charge level of said storage battery is reached, removing the prohibition upon reaching a certain discharge level of said storage battery, prohibiting the work of the respective discharge device when the maximum discharge level of said storage battery is reached, and removing this prohibition upon reaching a certain charge level of said storage battery. The load is divided into the duty and the session components, and when the maximum discharge level of any storage battery is reached, the session part of the load is disconnected, and prohibiting the work of the respective discharge device is established after disconnecting the session part of the load.

EFFECT: ensuring normal disconnection of the session load in case of an abnormal situation.

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Description

The invention relates to electrical engineering, namely, power supply systems (SES) of spacecraft (SC), using solar batteries (SB) as primary energy sources, and storage batteries (AB) as energy storage devices.

A known method of controlling an autonomous power supply system (RF patent No. 2059988, H02J 7/35) containing a solar battery (SB), a voltage regulator included between the solar battery and the load, "n" batteries (n≥1) and "n" (according to the number of batteries) of charging and discharging devices, as well as for each battery - devices for controlling the degree of charge.

In the known SES, the voltage stabilizer, charging and discharge devices are continuously controlled depending on the input (voltage of the SB) and the output voltage of the SES. At the same time, the chargers provide a charge for the battery, and the voltage stabilizer and discharge device provide power to consumers.

The continuous control (feedback) circuits of the charger are connected to the SB bus and the load bus, and the continuous control circuits of the voltage stabilizer and discharge device are connected to the load bus.

Depending on the degree of charge or discharge of the battery, a prohibition or authorization of the operation of the charger and the discharge device is carried out.

Such management provides long-term autonomous operation of the SES. However, it does not ensure the preservation of the performance of SES in case of emergency or emergency situations on the spacecraft. In the event of an abnormal, unplanned violation of the orientation of the solar cells of the spacecraft to the sun, a violation of the energy balance in the SES occurs. If the loss of orientation is long enough, a complete discharge of all batteries may occur. Food on-board consumers will then stop.

A known method of controlling an autonomous power supply system (RF patent No. 2168828, H01J 7/36) containing a solar battery and n rechargeable batteries, where n≥1 is a voltage regulator connected between the solar battery and the load and n charge and discharge devices, which consists in control the voltage stabilizer and charge-discharge devices depending on the input and output voltage of the system, control the degree of charge and discharged batteries, prohibit the operation of the corresponding charger p Upon reaching the maximum charge level of a given battery, removing this prohibition upon reaching a certain level of discharging a given battery, prohibiting the operation of a corresponding discharge device when reaching a maximum level of discharging a given battery, lifting this prohibition upon reaching a certain charge level of a given battery, characterized in that in the case of a loss of orientation of solar panels in the sun, emergency discharge of battery batteries and disconnecting some of the discharge devices, when the power of the remaining discharge devices is not enough to power the load, the operation of all discharge devices is prohibited, and the discharge devices are no longer controlled by signals about the level of charge, after restoring the orientation of the solar batteries to the Sun, the batteries are first charged to a certain value of the capacitance, and then enable the operation of the discharge devices and resume control of the discharge devices by signals about the level of charge .

This method is adopted as a prototype of the claimed invention.

The known method solves the problem of preventing the failure of batteries AB, restore the normal functioning of the SES after an emergency or emergency. However, the known method involves the complete removal of power from the spacecraft load, which does not guarantee regular shutdown of the session load.

The task of the invention is to ensure regular shutdown of the session load in case of emergency.

The problem is solved in that in the proposed method, when controlling an autonomous power supply system of a spacecraft containing a solar battery and n rechargeable batteries, a voltage stabilizer connected between the solar batteries and the load and n charge and discharge devices, which consists in controlling the voltage stabilizer and discharge devices depending on the input and output voltage of the system, monitoring the degree of charge and discharged batteries, the prohibition of work the corresponding charger when reaching the maximum charge level of a given battery, removing this prohibition when a certain level of discharge of a given battery is reached, prohibiting the operation of a corresponding discharge device when reaching a maximum level of discharging a given battery, lifting this ban when a certain level of charge of a given battery is reached , the load is divided into standby and session components and when the limit is reached at a low discharge level of any battery, the session part of the load is disconnected, and the ban on the operation of the corresponding discharge device is established after the session part of the load is disconnected.

During the operation of the spacecraft during the discharge of any battery to the lower set level, the session part of the load is disconnected, and the ban on the operation of the corresponding discharge device is established after the session part of the load is disconnected.

After disconnecting the corresponding discharge device, the load is powered by the remaining switched on discharge devices from other batteries that have not yet reached the established limit level of discharge.

In this case, the spacecraft’s power consumption when the load part of the load is off will be much less, which gives time for (maneuver) elimination of the cause of the abnormal deep discharge of the battery.

As an example, in FIG. 1, a variant of a functional diagram of an autonomous spacecraft power supply system for implementing the inventive method is given.

The autonomous power supply system of the spacecraft contains: a solar battery 1 connected to the load 2 through a voltage converter 3, rechargeable batteries 4 ₁ -4 _n connected via charging converters 5 ₁ -5 _n to the solar battery 1, and through discharge converters 6 ₁ -6 _n to the input of the output filter of the voltage converter 3. In addition, the batteries 4 ₁ -4 _n contain bypass discharge circuits consisting of diodes connected in parallel to each battery in the discharge direction.

At the same time, load 2 is functionally divided into standby 2-1 and session 2-2 components and includes an on-board computer, a telemetry system, and a command and measurement radio link.

In parallel with the batteries 4 ₁ -4 _{n, the} battery monitoring devices 7 ₁ -7 _n are connected, connected to the input to the batteries 4 ₁ -4 _n to control the voltage, pressure and temperature of the batteries, and the output with a load of 2. In addition, the battery monitoring devices batteries 7 ₁ -7 _n contain discharge resistance (not shown in the diagram) for conducting preventive discharges of batteries 4 ₁ -4 _n .

Measuring shunts 8 ₁ -8 _{n are} installed in the battery charge-discharge circuit.

Charging converters 5 ₁ -5 _n consist of a control key 9, controlled by a control circuit 10, a voltage boost unit made on a transformer 5-5, transistors 5-1 and 5-2 and a rectifier on diodes 5-3 and 5-4.

Bit converters 6 ₁ -6 _n consist of a control key 11, controlled by a control circuit 12.

The voltage converter 3 consists of a control key 13 controlled by a control circuit 14, an input filter on a capacitor 3-1 and an output filter on a diode 3-2, a choke 3-3 and a capacitor 3-4.

Control schemes: 10 charging converters 5 ₁ -5 _n , 12-bit converters 6 ₁ -6 _n , 14 - voltage converters 3, are made in the form of pulse-width modulators, the input connected to the stabilized voltage buses. The control circuit 10 of the charging converters 5 ₁ -5 _{n are} additionally associated with the measuring shunts 8 ₁ -8 _n and load 2.

The device operates as follows. During operation, rechargeable batteries 4 ₁ -4 _n work mainly in storage mode and periodic recharges from the solar battery 1 through charging converters 5 ₁ -5 _n . This mode of operation allows you to keep them in constant readiness for emergencies (loss of spacecraft orientation to the Sun) or for the passage of regular shadow areas of the orbit.

Power supply load 2 is provided from the solar battery 1 through the voltage Converter 3.

When passing shadow portions of the orbit, or if the spacecraft’s orientation to the Sun is disturbed, load 2 is powered by rechargeable batteries 4 ₁ -4 _n through discharge converters 6 ₁ -6 _n .

Monitoring devices 7 ₁ -7 _n control the voltage, pressure and temperature of the battery batteries 4 ₁ -4 _n and transmit information about their condition to the load 2.

During the operation of the spacecraft, according to the results of the analysis of information about the state of the battery (mainly the voltage of the batteries and the battery as a whole), a command is generated by shutting down the session part of the load 2-2, or after the process is completed, according to the hardware logic or pre-stored in the on-board computer shutdown a ban on the operation of the corresponding bit device.

The need to complete the process of disconnecting the session part of the load before blocking the discharge device is due to the fact that the regular disconnection of the session part of the load is performed according to a given sequence diagram, is a time-consuming process, and may not be ensured when all discharge devices are blocked with a simultaneous power failure on the output side buses of the SES . This situation will arise, for example, in the event of an abnormal loss of orientation of the solar cells of the spacecraft to the sun.

After the restoration (partial or full) of the orientation of the solar panels on the Sun and the evaluation of telemetry data, the ban is removed by command from the Earth.

Thus, the inventive method of controlling an autonomous power supply system of the spacecraft provides a regular shutdown of the session load in case of emergency.

Claims (1)

A method for controlling an autonomous power supply system of a spacecraft containing a solar battery and n rechargeable batteries, a voltage stabilizer included between the solar batteries and the load and n charging and discharging devices each, comprising controlling a voltage stabilizer and charge-discharge devices depending on the input and output voltage system, monitoring the degree of charge and discharged batteries, the prohibition of the operation of the appropriate charger when reaching a specific charge level of a given battery, lifting this prohibition upon reaching a certain level of discharging a given battery, prohibiting the operation of a corresponding discharge device when reaching a maximum level of discharging a given battery, and lifting this prohibition upon reaching a certain charge level of a given battery, characterized in that the load is divided into standby and session components and when reaching the maximum level of discharge of some a battery carried disconnection of session part load, and ban on the operation of the corresponding discharge cell is set after the disconnection of session part load.

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