RU2059988C1 - Autonomous power supply for satellite - Google Patents

Abstract

FIELD: power supply units. SUBSTANCE: device has solar battery, which is connected to load through series converter, accumulator batteries, which are connected to solar batteries through charge converters and to load through discharge converters. Each converter has control circuit, which provides information about current and voltage parameters, which are output by converter. Output voltage feedback wires of discharge converters are connected to control circuits through stabilization level switches, which are connected to protection circuits of accumulator batteries and load. During operation cycle level of stabilization of discharge converters is periodically switched. This results in possibility of automatic running routine checks of accumulator batteries. EFFECT: increased reliability. 1 dwg

Description

 The invention relates to electrical engineering, namely to autonomous satellite power supply systems with a long service life.

 A characteristic feature of such power supply systems is a significant excess of the initial energy characteristics of primary sources of electricity (solar panels) and secondary sources of electricity (batteries) over the actual consumption of satellite equipment onboard due to subsequent resource degradation changes.

 Autonomous power supply systems [1] are known which contain solar batteries, rechargeable batteries with protection circuits connected to the solar battery and the load through charging and discharge converters.

 In this case, the power control of the solar battery is carried out by parallel (shunt) converters, or sequential (serial) converters.

 With regard to autonomous satellite power supply systems with a long service life, regulating the power of the solar battery by means of a series converter is more preferable, because, firstly, there is no need to calculate the converter for the entire initial power of the solar battery, and secondly, there is the possibility of extreme power control, which allows more efficient use of the power of the solar battery, which is especially important at the end of a long life of the satellite.

Also known is an autonomous power supply system with a serial converter [2] and with a parallel converter [3]
The closest in technical essence of the proposed autonomous power supply system of the satellite is an autonomous power supply system [4] prototype.

 A disadvantage of the known autonomous power supply systems is the inability to conduct preventive battery cycles with optimal charge-discharge modes, which reduces their resource capabilities and reliability.

 The aim of the invention is to increase the resource characteristics and reliability of an autonomous satellite power supply system.

 This goal is achieved by the fact that feedbacks on the output voltage of the discharge converters are connected to the control circuits via stabilization level switches associated with the battery protection circuits and the load.

The drawing shows a functional diagram of the proposed autonomous power supply system of the satellite. The system contains a solar battery 1 connected to load 2 through a serial converter 3, rechargeable batteries 4 ₁ -4 _n with protection circuits 5 ₁ -5 _n , connected via charging converters 6 ₁ -6 _n to the solar battery 1, and through discharge converters 7 ₁ -7 _n to the load (output filter of the serial converter 3). Each converter contains a control circuit 9, 10, 24, made in the form of a pulse-width modulator and associated with the output of the converter for voltage and current. Current feedback is taken for charging 6 ₁ -6 _n and discharge 7 ₁ -7 _n converters from shunts 11 ₁ -11 _n in the charge-discharge circuit of rechargeable batteries 4 ₁ -4 _n and from shunt 25 in load circuit 2 for a serial converter 3. Feedback on the output voltage of the discharge converters are connected to the control circuits 10 through the stabilization level switches 8 ₁ -8 _n , associated with the protection circuits 5 ₁ -5 _n batteries 4 ₁ -4 _n and load 2.

The charging converter 6 consists of a control key (transistor) 13, controlled by a control circuit 9, a voltage boost assembly made on a transformer 14 and transistors 12 ₁ , 12 ₂ , a rectifier on diodes 15 ₁ , 15 ₂ .

 The bit converter 7 consists of a control key (transistor) 16, controlled by a control circuit 10.

 The serial converter 3 consists of a control key 19 controlled by a control circuit 24, an input filter capacitor 20 and an output filter on the inductor 22, diode 21 and capacitor 25.

 The stabilization level switch 8 is essentially a resistor 17 in the power circuit of the control circuit 10, shunted by the contacts of the relay 18, controlled by load 2 and the battery protection circuit.

 The protection circuit of the battery 5 in the drawing is not disclosed, since it can consist of a different set of functional units, depending on the type of battery and its requirements (monitoring the minimum and maximum voltage of the battery or each battery, monitoring pressure and temperature sensors, monitoring the current capacity etc.).

The system operates as follows. With the power of the solar battery 1, the voltage at the load 2 is stabilized by a series converter 3. Current feedback from shunt 25 protects the series converter 3 from overload. The excess power of the solar battery 1 is used to charge the batteries 4 ₁ -4 _n through the charging converters 6 ₁ -6 _n . The current feedback from the shunts 11 ₁ -11 _n limit the charge currents at a given level, and the voltage feedback limits the charge currents from the condition of the presence of excess power of the solar battery by limiting the charge currents when the voltage of the solar battery is reduced to: load voltage 2 plus ( 1-2) V (voltage drop across the power switch 19 of the serial converter 3).

With a lack or absence of power of the solar battery 1, the voltage at the load 2 decreases, and the discharge converters 7 ₁ -7 _n begin to give the missing power from the batteries 4 ₁ -4 _n to the load 2 from the condition of ensuring the set stabilization level (in practice, the stabilization level of the discharge converter 0.2-0.4 V below the stabilization level of the serial converter). Current feedback limits discharge currents.

During the operation of charging 6 ₁ -6 _n and bit 7 ₁ -7 _n converters, protection circuits 5 ₁ -5 _n rechargeable batteries 4 ₁ -4 _n monitor their condition and provide control actions on charging converters 6 ₁ -6 _n (turning on, turning off ) and the load (if necessary, reset the session load when the battery is completely discharged).

To achieve this goal, switches 8 ₁ -8 _{n of} the voltage stabilization level of discharge converters 7 ₁ -7 _n are connected to the autonomous power supply system. They are connected with protection circuits of 5 ₁ -5 _n batteries and a load of 2. A preventive cycle signal is issued from the load side one of the batteries to the corresponding stabilization level switch 8.

 Such a signal can be generated by an onboard satellite computer, or issued via a command radio link from a control center from the Earth. The stabilization value of the discharge converter 7 rises above the stabilization voltage of the serial converter 3, while the corresponding battery 4 begins to discharge into the load 2 with currents at the level of the established current limitation. At the same time, a signal is issued through the corresponding protection circuit 5 of the battery to prohibit the operation of the corresponding charging converter 6. When the battery 4 is completely discharged, protection circuit 5 of the battery gives a signal to the stabilization level switch 8 to return to its original state. The discharge stops, the charge begins until it is terminated according to the corresponding logic by the protection circuit 5 of the battery. In the same way, preventive cycles of other storage batteries of an autonomous satellite power supply system can be carried out.

 The entire process of conducting preventive cycles is implemented during the operation of the satellite in automatic mode, sequentially with each battery, which increases the resource characteristics of the satellite’s autonomous power supply system and its reliability.

Claims (1)

 The stand-alone power supply system of the ARTIFICIAL SATELLITE OF THE EARTH, containing a solar battery connected to the load via a serial converter, n rechargeable batteries with protection circuits connected through the charging converters to the solar battery, and through the discharge converters to the load, each converter containing a control circuit configured as pulse-width modulator containing measuring organs of the output voltage and current of the Converter, characterized in that, in order to increase it resource characteristics and reliability, the measuring organs of the output voltage of the discharge converters are connected to their outputs through the stabilization level switches associated with the battery protection circuits and the load, and the battery protection circuits are connected with the charging and discharge converters and the load.

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