RU2461102C1 - Method for operation of lithium-ion accumulator battery in autonomous power supply system - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention may be used to develop and operate lithium-ion accumulator batteries in autonomous power supply systems, mainly - those of artificial Earth satellites (AES). The method for operation of a lithium-ion accumulator battery in an autonomous power supply system consists in conductance of charges, storage in charged condition, recharges, discharges, accumulators voltage control and accumulators periodical voltage balancing by way of selecting the accumulators with the lowest voltage and discharge of the other accumulators to individual balancing resistors depending on their voltage initial magnitude until the preset end level. According to the invention, the other accumulators discharge to balancing resistors is performed successively, one by one; each time it is the accumulator with the lowest current voltage that is subjected to discharge to a balancing resistor.

EFFECT: increased efficiency of usage and simplification of operation of a lithium-ion accumulator battery in an autonomous power supply system.

4 cl, 1 dwg

Description

The claimed invention relates to the electrical industry and can be used in the development and operation of lithium-ion batteries in an autonomous power supply system, mainly artificial Earth satellites (AES).

Known lithium-ion batteries and methods of their operation, consisting in conducting charge-discharge cycles and monitoring the voltage of the batteries and described in the book by A.A. Taganov, Yu.I. Bubnov, SB Orlov, Sealed chemical current sources. Elements and batteries. Equipment for testing and operation, St. Petersburg, chemical publishing house, 2005, chapter 5, 7.

However, in this work, the features of the technology of operation of lithium-ion batteries are not considered.

Known lithium-ion batteries and methods of their operation, consisting in conducting charge-discharge cycles and monitoring the voltage of the batteries and described in the book D.A. Khrustalev, Batteries, M., Emerald, 2003, Chapter 4. This paper notes very low internal resistance of the batteries and the ability to control charge-discharge processes only according to the current values of the voltage of the batteries. It is noted that overcharging and overdischarging of batteries is categorically unacceptable and protective equipment should be provided in batteries. However, the known information relates mainly to the ground-based use of lithium-ion batteries in mobile phones and computer equipment and does not solve the issues of reliable operation over a long life in the satellite.

The closest technical solution is a method of operating a lithium-ion battery, which consists of charge-discharge cycles, monitoring the voltage of the batteries and balancing the voltage of the batteries during operation by sub-discharging the batteries into resistors until the voltage reaches the voltage of the most discharged (least charged) voltage. battery (“Battery 6LI-25, ZhTsPI.563561.002 PS”, development and manufacture of the enterprise OJSC “Saturn”, Krasnodar).

In the well-known lithium-ion rechargeable battery 6LI-25, according to ZhTsPI.563561.002 PS, the voltage of the batteries is periodically monitored and, if the difference in the cell-by-cell voltages of the most charged and least charged batteries exceeds 25 mV, the batteries are aligned by capacity by discharging more charged batteries to balancing resistors to reduce the difference in battery voltage not more than 10 mV.

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

A disadvantage of the known method of aligning the batteries by capacity (by balancing the batteries by voltage) implemented by the known battery is that the beginning of the alignment of the batteries by capacity is associated with the achievement of a predetermined voltage unbalance, which reduces the efficiency of using a lithium-ion battery. In addition, the balancing process is associated with heat generation on the balancing resistors, which complicates the operation of the battery.

The task of the invention is to increase the efficiency of use and simplify the operation of a lithium-ion battery in an autonomous power supply system.

The problem is solved in that when carrying out charges, storing in a charged state, recharging, discharging, monitoring the voltage of the batteries and periodically balancing the batteries by voltage, by choosing the battery with the lowest voltage and discharging other batteries to individual balancing resistors, depending on their initial value voltage, to a specified final level, the discharge to the balancing resistors of other batteries is carried out one at a time, and each time the discharge The battery with the highest current voltage is exposed to the balancing resistor. In this case, the discharge to the balancing resistors of other batteries is limited by the minimum value of the set voltage difference between the batteries of the battery, and the minimum value of the set voltage difference by the batteries of the battery is regulated during operation of the battery to achieve the optimal result. In addition, the discharge to the balancing resistors of other batteries is carried out until the voltage of the discharged battery reaches the current value of the lowest voltage from all batteries of the battery.

The proposed method of balancing batteries by voltage is implemented within the framework of requirements for permissible unbalancing of batteries by capacity (voltage), while allowing to reduce the permissible unbalance of batteries by capacity to almost zero, which increases the efficiency of using the battery in an autonomous power supply system. At the same time, the balancing process does not impose any restrictions on the operation of the power supply system (AES), it is carried out regardless of any external (for example, temperature) factors and the operating mode of the battery (charge, discharge, storage), which simplifies the operation of a lithium-ion battery in an autonomous power supply system. The heat dissipation from the balancing resistors during balancing is an order of magnitude (or more) lower than in the prototype, and the potential decrease in the output power of the battery, due to a decrease in the voltage of one battery by several millivolts, is negligible.

In the drawing, FIG. 1, a simplified functional diagram of an autonomous satellite power supply system is illustrated, explaining the work of the proposed method.

The device comprises a solar battery 1 connected to the load 2 through a voltage converter 3, a battery 4 connected through a charging converter 5 to the solar battery 1, and through a discharge converter 6 to the input of the output filter of the voltage converter 3.

At the same time, load 2 in its composition contains an on-board computer, a telemetry system and a command-measuring radio line.

In parallel with the battery 4, a battery monitoring device 7 (in particular, the battery voltage) of the battery is connected, connected to the input with the battery 4, and the output with a load of 2 (with the on-board computer).

A measuring shunt 8 is installed in the charge-discharge circuit of the battery.

The battery consists of series-connected batteries 4-1, in parallel with which balancing resistors 4-2 are connected through the closing contacts 4-3 of the relay in the relay block 4-4.

The charging converter 5 consists of a control key 9, controlled by a control circuit 10, a boost assembly made on a transformer 15, transistors 16 and a rectifier on diodes 17.

Bit Converter 6 consists 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 the capacitor 18 and an output filter on the diode 19, the inductor 20 and the capacitor 21.

Control circuits: 10, charging converter 5, 12, discharge converter 6, and 14, voltage converter 3, are made in the form of pulse-width modulators, inputs connected to stabilized voltage buses. The control circuit 10 of the charging Converter 5 is additionally connected with the measuring shunt 8 and the load 2, as feedbacks on the magnitude of the charging current and load voltage, respectively.

The device operates as follows. During operation, the battery 4 operates mainly in the storage mode and periodic recharges from the solar battery 1 through the charging converter 5. This operating mode allows you to keep it in constant readiness for the passage of regular shadow areas of the orbit or in case of loss of orientation of the solar satellite satellite in the sun.

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

When passing shadow portions of the orbit or in violation of orientation, the load 2 is powered by the battery 4, through the discharge converter 6.

The battery monitoring device 7 monitors the voltage of the batteries and transmits information about their condition to load 2, in which the following technological operations are implemented:

1. Data on the current value of the battery voltage is processed, the current battery capacity and the difference in the current battery capacity (voltage) are estimated.

2. When the current capacity (voltage) of the batteries decreases to a certain value selected at the design stage of the power supply system, the charge (recharge) of the battery is unlocked and, in the presence of excess power of the solar battery 1, the charge of the battery 4 is turned on. If the difference in the current battery capacity of 4-1 essential values (the minimum value of the set voltage difference of the battery batteries) starts the process of balancing the batteries voltage uw. The lowest and highest battery voltage in the battery and the number of these batteries are recorded.

An individual discharge resistor 4-2 is connected to the battery 4-1 with the highest voltage (by closing the corresponding contact 4-3 of the relay block of the relay 4-4). When aligning the voltage value of the balanced battery with the current voltage of the battery having the lowest voltage value, a command is formed to disconnect the corresponding individual discharge resistor 4-2 by opening the corresponding contact 4-3 of the relay block of the relay 4-4. The control of the relay block 4-4 is implemented, according to the program in the on-board computer, through the battery monitoring device 7.

The process is then repeated for another battery having the highest current voltage and so on. The balancing process can be suspended with the current absence of batteries in the battery with a voltage difference higher than the minimum value of the set voltage difference between the batteries, until they appear.

3. During the operation of the battery, according to the results of the analysis of telemetric data on the magnitude of the battery voltages by commands from the Earth through the command and measurement radio line, the minimum value of the set voltage difference between the battery voltages of the battery can be adjusted to achieve the optimal result.

Thus, the proposed method improves the efficiency of use and simplifies the operation of a lithium-ion battery in an autonomous power supply system.

Claims (4)

1. The method of operation of a lithium-ion battery in an autonomous power supply system, which consists in carrying out charges, storing in a charged state, recharging, discharging, monitoring the voltage of the batteries and periodically balancing the batteries by voltage, by selecting the battery with the lowest voltage and discharging other batteries to individual balancing resistors, depending on the initial value of their voltage, to a set final level, characterized in that the discharge on the balancing The resistors of other batteries are alternately carried out one at a time, and each time the battery with the highest current voltage is exposed to the balancing resistor. 2. The method of operating a lithium-ion battery in an autonomous power supply system according to claim 1, characterized in that the discharge to the balancing resistors of other batteries is limited by the minimum value of the set voltage difference of the battery batteries. 3. The method of operating a lithium-ion battery in an autonomous power supply system according to claim 1, characterized in that the minimum value of the set voltage difference of the battery batteries is regulated during operation of the battery to achieve the optimum result. 4. The method of operating a lithium-ion battery in an autonomous power supply system according to claim 1, characterized in that the discharge to the balancing resistors of other batteries is carried out until the voltage of the discharged battery reaches the current value of the lowest voltage from all batteries of the battery.