RU2331954C1 - Method of nickel-hydrogen battery operation in artificial earth satellite stand-by power supply system - Google Patents

Abstract

FIELD: electricity; physics.

SUBSTANCE: according to invention, method of nickel-hydrogen battery operation in artificial earth satellite stand-by power supply system includes charge-discharge cycles with limiting charging by pressure sensors installed on control batteries of the main battery, battery storage in full-charge state and periodic recharging to compensate battery self-discharge capacity during storage. Self-discharge currents in control batteries are additionally controlled by external discharge circuit. External discharge circuit can be made as: - resistor with R=1.25/(Is_max - Is_contr), where Is_max - maximum current of battery self-discharge and Is_contr - self-discharge current of control battery, -series circuit consisting of diode and resistor with R=(1,25 - U_D)/(Is_max -Is_contr), where U_D - voltage drop at diode, Is_max - maximum current of battery self-discharge and Is_contr - self-discharge current of control battery; - series circuit of two diodes and resistor with R=(1.25 - 2U_D)/(Is_max - Is_contr), where U_D - voltage drop at diode, Is_max - maximum current of battery self-discharge and Is_contr - self-discharge current of control battery; - current stabiliser. Also, external discharge circuit is switched during battery operation and time of on-line state is controlled depending on current battery capacity. Level to stabilised current is controlled during battery operation within the range from 0 A to (Is_max - Is_contr) A, where Is_max -maximum current of battery self-discharge and Is_contr - self-discharge current of control battery.

EFFECT: increase in nickel-hydrogen battery effectiveness of use and improvement of reliable operation.

6 cl, 6 dwg

Description

The invention relates to the electrical industry and can be used in the operation of nickel-hydrogen storage batteries mainly in stand-alone power systems for artificial Earth satellites (AES).

When using nickel-hydrogen storage batteries in a satellite, the main work falls on the period of shadow orbits. The rest of the time in solar orbits, with the exception of the moments when the power of the solar battery is insufficient to ensure the consumption of the load, the battery operates in storage mode with periodic recharges to compensate for self-discharge.

The main reason for the decrease in capacitive characteristics of nickel-hydrogen storage batteries is the imbalance of the batteries in capacity during its operation. This is due to an objective difference in the magnitude of self-discharge currents of individual batteries. During operation of the rechargeable battery, its charge is limited by the most charged batteries, and the discharge by the least charged batteries. Therefore, the greater the degree of imbalance of the batteries in terms of capacity, the lower the capacity of the battery.

Given that the value of the self-discharge current increases depending on the degree of charge of the battery, it is important to choose the degree of charge of the control batteries to limit the charge (recharge) of the battery.

A known method of operating a Nickel-hydrogen battery (patent No. 2084055, Н01М 10/44), according to which the charge of the battery is limited based on the density of hydrogen, calculated on the basis of the measured pressure and temperature of the batteries, which provides battery charge to a level (60-80 )% of nominal capacity.

The disadvantage of this method is that it does not allow efficiently (at the level of (80-90)% of the nominal capacity) to operate the battery for a long life. This is due to the fixed values of the controlled parameters (hydrogen density) for the termination or resumption of charge, without taking into account resource changes in the operation of the battery.

A known method of operating a Nickel-hydrogen battery (ed. St. No. 1746443, H01M 10/44, 12/06), in which the control of charge-discharge cycles is carried out by a two-pressure sensor with a difference in the pressure settings P and temperature, and the discharge ends minimum voltage, when the battery reaches the minimum voltage value, the settings of the pressure sensor are periodically increased, and the lower setting is increased to the level of the upper, and the upper - by P.

This method allows a resource increase in the controlled parameter (hydrogen pressure), however, a limited number of pressure settings and the discrete nature of the transition from one setting to another reduces its efficiency and does not allow for a constantly high degree of charge of the battery.

In this case, with increasing temperature of the batteries (after switching to a higher control pressure level) above the calculated value, the phenomenon of the so-called “thermal acceleration” may develop, consisting in the fact that a further increase in temperature during recharging causes a more intense release of oxygen from the positive electrode and increases activity negative electrode, which in turn increases the rate of recombination of oxygen with hydrogen and intensifies heat release. As a result, the process develops with positive feedback.

In this case, the set control value of the hydrogen pressure may not be reached. This reduces the reliability of the known method.

The closest in technical essence to the proposed method is the method according to the application No. 2005122357/09 (025199) from 07/14/2005 (decision to grant a patent for the invention of September 5, 2006, patent No. 2294580), which consists in conducting charge-discharge cycles with charge limitation by analog pressure sensors installed on separate batteries of the battery, storage in a charged state and periodic recharging to compensate for the capacity of self-discharge of batteries during storage, while installing analog pressure sensors ivayut on batteries located in the most thermally stressed conditions, and then charged on and off is performed from the condition of ensuring a steady Spent batteries self-discharge current analog pressure sensors equal to a certain value, taken as a prototype.

The known method, based on the self-discharge rate of the control batteries, allows you to achieve almost the maximum possible degree of alignment of the batteries in the battery in terms of capacity and, therefore, the maximum degree of charge of the battery as a whole.

The disadvantage of this method is that to achieve a high degree of alignment of the batteries in the battery in terms of capacity, the charge of the control batteries is carried out to a higher level, which increases their average operating temperature and negatively affects their resource characteristics.

In addition, during the operation of the battery, its “temperature field” can change (for example, if one of the batteries fails, which is allowed), and the control battery can get out of the requirement “in the most heat-stressed conditions”. This will lead to a decrease in battery efficiency.

It should also be noted that a significant recharge of the control battery can lead to its "thermal acceleration", which reduces the reliability of the battery, and reaching a higher temperature level will increase the self-discharge rate, which reduces the efficiency of use of the battery.

Indeed, if the control battery has sufficient capacity, then it is undesirable to expose it to a higher degree of charge, which will negatively affect its resource characteristics.

The aim of the invention is to increase the efficiency and reliability of the Nickel-hydrogen battery.

This goal is achieved in that the regulation of the magnitude of the self-discharge currents of the control batteries is additionally carried out using an external discharge circuit.

In this case, the external discharge circuit can be made in the form of:

- the value of the resistor R = 1,25 / (Ic _max -Ic _simp), where Ic _max - maximum battery self-discharge current, and Ic _simp - self-discharge current of the battery manager,

- a series circuit of a diode and a resistor value of R = (1,25-Ud) / (Ic _max -Ic _simp), where Ud - the voltage drop across the diode, Ic _max - maximum battery self-discharge current, and Ic _simp - self-discharge current of the battery control ;

- a series circuit of two diodes and a resistor value of R = (1,25 - 2Ud) / (Ic _max -Ic _simp), where Ud - the voltage drop across the diode, Ic _max - maximum battery self-discharge current, and Ic _simp - self-discharge current of the control battery;

- current stabilizer.

In addition, the external discharge circuit is switched during operation of the battery, and the time spent in the connected state is controlled depending on the current capacity of the battery, and the level of stabilized current is regulated during operation of the battery in the range from 0 A to (Ic _max -Ic _exercise ) A, where Ic _max is the maximum self-discharge current of the batteries, and Ic _exercise is the self-discharge current of the control battery.

In the process of conducting charge-discharge cycles or periodic recharges of the battery, the self-discharge currents of all batteries come to a single value (steady-state value). This happens automatically - each battery reaches a charge level at which its self-discharge current is compared with the self-discharge current of the control battery. Accordingly, a battery having an objectively largest self-discharge will reach the steady-state lowest charge level.

Absolutely identical batteries, but located in different temperature conditions, also lead to an imbalance in capacity if a cooler battery is selected as the control battery. Switching to battery charge control with an increase in the upper setting reduces the risk of imbalance, but can lead to increased battery heat, which is also undesirable.

The negative effect of the spread of self-discharge currents is compensated if the control batteries are in the same temperature conditions and in the warmest sectors of the battery design, which guarantees the self-discharge current of these batteries is greater than the self-discharge currents of the remaining batteries and eliminates the unbalance phenomenon.

A different way to achieve this condition is proposed. This is an artificial control of the self-discharge current of control batteries by creating an external discharge circuit on the control battery.

Indeed, if the capacity of the control battery itself is at a sufficiently high level, then there is no need to recharge it to increase its self-discharge current, but it will be enough to artificially organize an increase in its self-discharge by introducing an external discharge circuit.

At the same time, the achieved effect of aligning the batteries in the battery in terms of capacity will not change.

At the same time, the heat emission of the control battery will be reduced, the possibility of realizing a higher degree of alignment of the batteries in terms of capacity due to the removal of restrictions on the self-discharge current of the control battery itself (the need to install it in the most heat-stressed place) will be significantly expanded, and the negative impact of a potential change temperature of the control battery in the "temperature field" of the battery.

Figure 1 shows the options for the external discharge circuits of the controlled battery of the battery, where 1 is the control battery, 2 is the resistor, 3 is the diode (s), 4 is the switch of the shunt circuit, which has a control connection “Exercise” (for example, the load of the autonomous power supply system - on-board computer), 5 - current stabilizer input connected to the power source (for example, to the output buses of the autonomous power supply system, figure 2) Upit and having control connection "Exercise" (for example, with the load of the autonomous power supply system - on-board computer).

In the simplest case, the external discharge circuit is a calculated value resistor 2 connected to the terminals of the control battery 1 - option a).

If it is necessary to limit the voltage level of battery 1, at which it is discharged to an external discharge circuit, then diodes 3 are connected in series with resistor 2 - one, option b), or two, option c). In this case, the discharge of the battery 1 to the external discharge circuit will stop after the voltage across it drops to the closing voltage of the diode (s) 3. This is advisable if during the operation of the battery there are periods of storage without recharging in order to reduce the probability of battery discharge to voltage 0 V, which adversely affects his subsequent work.

The introduction of the switch 4 into the external discharge circuit of the control battery, option d), or the current stabilizer 5, option e), which are connected with the control “Ex.”, For example, with the load of the autonomous power supply system - the on-board computer, allows you to adjust the value during operation of the battery discharge capacitance of the control battery to an external discharge circuit. This increases the "flexibility" of the method of operating the battery, its efficiency and reliability.

The resistance value of resistor 2 is calculated based on the average discharge voltage of the nickel-hydrogen battery 1.25 V. In this calculation, specific data on the voltage drop across the diodes Ud used, as well as self-discharge currents are used: the maximum possible self-discharge current of any battery in a specific battery the battery under specific operating conditions Ic _max and self-discharge current of the control battery of this battery Ic _exercise .

Figure 2 shows the functional diagram of an autonomous power supply system, explaining the work of the proposed method.

The device contains a solar battery 6 connected to the load 7 through a voltage converter 8, a battery 9 connected through a charging converter 10 to the solar battery 6, and through a discharge converter 11 to the input of the output filter of the voltage converter 8.

In this case, the load 7 in its composition contains an on-board computer, a telemetry system and a command and measurement radio line.

In parallel with the battery 9, a control device for controlling the control batteries 12 is connected (in particular, monitoring the pressure of the batteries, which determines their current capacity, and, if necessary, controlling self-discharge by means of a current stabilizer 5 or a resistor 2 switched by switch 4, Fig. 1), connected the input with the battery 9, and the output with a load of 7 (with the onboard computer).

In the circuit of the charge-discharge of the battery installed measuring shunt 13.

The charging Converter 10 consists of a control key 14, controlled by a control circuit 15, a boost assembly made on a transformer Tr, transistors T1 and T2 and a rectifier on diodes D1 and D2.

The bit converter 11 consists of a control key 16 controlled by a control circuit 17.

The voltage converter 8 consists of a control key 18 controlled by a control circuit 19, an input filter C1 and an output filter on a diode D, inductor L and capacitor C.

The control circuits of the converters 15, 17, 19 are made in the form of pulse-width modulators input connected to the stabilized voltage buses. The control circuit 15 of the charge Converter 10 is additionally associated with the measuring shunt 13 and the load 7.

The device operates as follows. During operation, the rechargeable battery 9 operates mainly in storage mode and periodic recharges from the solar battery 6 through the charging converter 10. This mode of operation allows you to keep it in constant readiness in case of emergencies (loss of satellite orientation on the Sun).

The load 7 is supplied from a solar battery 6 through a voltage converter 8.

When passing shadow portions of the orbit or in violation of orientation, the load 7 is powered by the battery 9 through the discharge converter 11.

The battery monitoring device 12 monitors the pressure in the batteries and transmits information about their condition to the load (on-board computer).

A program is implemented in the on-board computer that implements the following actions:

1. The data of analog pressure sensors in the control accumulators is processed with the calculation of the pressure value (or degree of charge).

2. The pressure value of the control accumulators (or the degree of charge) is compared with the values of the upper and lower pressure settings embedded in the charge control logic. If the upper set point is exceeded, the charging converter turns off, when it decreases below the lower set point, it turns on again.

3. The steady-state value of the self-discharge current of the battery is calculated by the formula: Jc = P _i / t · k, where P _i is the difference between the settings in Ah; t is the self-discharge time in hours; k is the calculated coefficient of decrease in the actual current of self-discharge in the case of switching the discharge circuit (equal to 1.0 if the discharge circuit is not switched).

4. During operation of the battery with periodic additional charges, the settings (upper and lower) are set so that the value of the self-discharge current (including the discharge current to the shunt circuit) of the batteries with analog pressure sensors is in the desired interval. In this case, when using a controlled current stabilizer as a shunt circuit or when switching a shunt circuit, the self-discharge current is regulated depending on the current capacity of the battery.

Thus, the proposed method of operating a nickel-hydrogen storage battery allows the latter to be maintained at a high level of charge during the passage of shadow orbits and to ensure storage in a charged state in solar orbits without compromising performance and, therefore, improves the efficiency and reliability of operation of a nickel-hydrogen battery , reliability of an autonomous power supply system and a satellite as a whole.

Claims (6)

1. A method of operating a nickel-hydrogen storage battery in an autonomous power supply system of an artificial Earth satellite, which consists in carrying out charge-discharge cycles with charge limitation by pressure sensors installed on the control batteries of the storage battery, storage in a charged state, periodic charging to compensate for the self-discharge capacity batteries during storage, control of self-discharge currents of control batteries and regulation of the magnitude of these currents by means of changed setting pressure sensors, characterized in that the regulation of the self-discharge currents of the control batteries is additionally carried out using an external discharge circuit. 2. A method according to claim 1, characterized in that the outer discharge circuit is designed as a resistor value of R = 1,25 / (Ic _max -Ic _simp), where Ic _max - maximum self-discharge current of the battery, a Ic _simp - self-discharge current of the control battery. 3. A method according to claim 1, characterized in that the outer discharge circuit is designed as a series circuit of a diode and a resistor value of R = (1,25-Ud) / (Ic _max -Ic _simp), where Ud - voltage drop across the diode , Ic _max is the maximum self-discharge current of the batteries, and Ic _control is the self-discharge current of the control battery. 4. A method according to claim 1, characterized in that the outer discharge circuit is designed as a series circuit of two diodes and a resistor value of R = (1,25-2Ud) / (Ic _max -Ic _simp), where Ud - the voltage drop across diode, Ic _max is the maximum self-discharge current of the batteries, and Ic _control is the self-discharge current of the control battery. 5. The method according to claim 1, characterized in that the external discharge circuit during operation of the battery is switched, and the time spent in the connected state is controlled depending on the current capacity of the battery. 6. A method according to claim 1, characterized in that the shunt circuit is formed as a current regulator, the current level is adjusted to be stabilized during the battery operation in the range of 0 A to (Ic _max -Ic _simp) A, where Ic _max - maximum self-discharge current of the batteries, and Ic _control is the self-discharge current of the control battery.

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