RU2289179C1 - Method for servicing nickel-hydrogen storage battery in off-line power supply system - Google Patents

Abstract

FIELD: electrical engineering; off-line power supply systems for geostationary artificial earth satellites.

SUBSTANCE: proposed method for servicing nickel-hydrogen storage battery in off-line power supply system includes battery charge-discharge cycles, bypassing of lower-capacity cells by means of bypass discharge diodes, voltage check across each cell, and trickle charge with low currents precluding explosion-hazard concentration of oxygen-hydrogen mixture. In the course of service polarity of separate cells of battery is reversed. In addition, polarity reversal capacity of cell first brought to minimal potential is checked from moment this voltage is attained till end of discharge; polarity-reversal capacity is calculated disregarding current through bypass discharge diodes and battery charge is started upon trickle charge with low currents at capacity being not lower than polarity-reversal value.

EFFECT: facilitated servicing of battery polarity of whose cells is periodically reversed.

1 cl, 1 dwg

Description

The present invention relates to the electrical industry and can be used in the operation of nickel-hydrogen storage batteries mainly in stand-alone power systems of geostationary satellites.

During operation of a nickel-hydrogen storage battery, its batteries are unbalanced in capacity. This may be due to unequal cooling conditions for individual batteries in the battery, differences in self-discharge currents, or the presence of internal microshunts in individual batteries. Therefore, the appearance in the process of discharging a battery of a completely discharged battery when the battery as a whole has sufficient capacity is naturally and constantly confirmed in practice.

With a further discharge of the battery, this battery undergoes a reverse polarity, which leads to the release of oxygen in it. To exclude oxygen evolution, the power of the hydrogen electrode is provided above the power of the positive electrode, or excess (ballast) hydrogen is introduced into the battery (see chapter XI, B.I. Center, N.Yu. Lyzlov "Metal-hydrogen electric systems, Leningrad," Chemistry ", Leningrad Branch, 1989 [1]).

Chemical reactions on the positive and negative electrodes, as exemplified by a nickel-hydrogen battery, when it is discharged, have the following form.

On the positive electrode: 2NiOOH + 2H ₂ O + 2e → 2Ni (OH) ₂ + 2OH ^- .

On the negative electrode:

- in the presence of ballast hydrogen 1 / 2H ₂ + OH ^- → H ₂ O + e;

- in the absence of hydrogen in the accumulator 2 (OH) ^- → 2е + 1 / 2O ₂ + Н ₂ O.

However, in modern rechargeable batteries, the existing requirement to increase their specific energy characteristics forces the developers of rechargeable batteries (in whole or in part) to neglect known techniques.

Known methods of operating Nickel-hydrogen batteries, providing for limiting the discharge by the minimum voltage of any of the batteries (see chapter X1.1.3. [1]), which does not allow to use the full energy capabilities of the battery, in other words, reduces the efficiency of use of the battery in whole.

A known method of operating a Nickel-hydrogen battery by conducting charge-discharge cycles, providing for "bypass" a fully discharged battery with diode (bypass) circuits (see WIBillerbeck, WEBaker "The desing of reliable power systems for communion ca-tions satelite", Comsat Laboratories Clarksbufg, AIAA / NASA Spacesyst. Technol. Conf. 14/8, 5-7 june, 1984).

The disadvantage of this method is that in the process of discharging the battery when the battery is completely discharged and the discharge continues, the battery is reversed (its polarity changes). The presence of a voltage drop on bypass diodes of (0.4-0.6) V value applied to this battery in reverse polarity promotes electrochemical reactions associated with oxygen evolution, which can lead to negative consequences for the battery (see chapter X1, [1]). In the worst case, the degree of polarity reversal of the battery is determined by the value of the capacitance passing through the battery, which reached the minimum voltage value, from the moment this voltage is reached to the end of the discharge without taking into account the currents through the bypass diodes, since when the batteries are overdischarged, the current through the bypass diodes lasts a long time not leaking.

There is a method of operating a metal-hydrogen storage battery in an autonomous power supply system by conducting charge-discharge cycles, which provides for monitoring the open circuit voltage of each battery and precharging with a small current until the open circuit voltage of all batteries is restored to a value not less than the voltage of their electrochemical pair (see application No. 2003112577/09 (013260) of 04/28/2003, the decision to grant a patent of 10/28/2004), which is selected as a prototype.

The disadvantage of this method is its certain complexity, both in terms of hardware performance (the need to control the voltage of the open circuit of each battery, and not their threshold values, which is much simpler), and software execution (varying the number of charging cycles depending on the results of measuring the voltage open battery circuit).

The aim of the invention is to simplify the technology of operation of a nickel-hydrogen storage battery, in which individual batteries are periodically reversed during operation.

This goal is achieved by the additional control of the capacity of the polarity reversal of the battery, which was the first to reach the minimum voltage value, from the moment this voltage is reached to the end of the discharge, and the polarity of the polarity is calculated without taking into account the currents through the bypass diodes, and the battery charge is low after pre-charging current with a message of capacitance not less than the obtained value of the polarity reversal capacitance.

Indeed, when oxygen appears in the battery (in the complete absence of hydrogen), it accumulates, and in the case of a subsequent active charge of the battery and intense hydrogen evolution, local zones with an explosive mixture are formed in the battery. The formation of such zones leads to microexplosions in the battery, and microexplosions lead to deformation of the elements of the electrochemical group and, as a result, to the appearance of internal shunts in the battery. As a result, this battery acquires increased self-discharge and, in the process of discharging the battery, is again reversed. Each time the process is more and more aggravated.

Internal microexplosions can be eliminated by dosed supply of a charging current (dosed evolution of hydrogen in the battery), which ensures stationary oxygen recombination at the hydrogen electrode and eliminates the appearance of local zones with explosive mixtures.

It was experimentally established that to restore the open circuit voltage (NRC) of a nickel-hydrogen battery to the value of its electrochemical pair (the standard value of the NRC for a nickel-hydrogen battery is 1.267 V (see [1], Table 1.1), guaranteeing the absence of oxygen in the battery) it is enough to tell him the charging capacity of at least the magnitude of the polarity reversal capacity.

So, during an experiment in which HB70 batteries were reversed at 5 Ah, the NRC restored to a value of 1.267 V after they were informed of a capacity from 1.3 Ah to 4.0 Ah. The difference in the required reported capacity until the NRC is completely restored is explained by the operation, to one degree or another, of a closed oxygen-hydrogen cycle in the process of battery reversal.

When using nickel-hydrogen storage batteries (especially on geostationary satellites, where the time interval between discharges (“shadows”) is about 23 hours and there is practically no limit on the time of charge), this feature allows us to significantly simplify the technology for operating a nickel-hydrogen storage battery, in which individual batteries are periodically reversed in both hardware and software.

Guaranteed recombination of oxygen released during overdischarge is provided by a simple preliminary recharging of the battery with a small current by the value of the capacity of the previous polarity reversal.

The drawing shows a functional diagram of an autonomous power supply system, explaining the work of the proposed method.

The device contains 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.

In this case, load 2 in its composition contains an on-board computer, a telemetry device, and a command and measurement radio line.

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

In the circuit of the charge-discharge of the battery is installed measuring shunt 8, associated with the load 2.

The charging converter consists of a control key 9, controlled by a control circuit 10, a boost booster made on a transformer Tr, transistors T1 and T2, a rectifier on diodes D1 and D2.

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 C1 and an output filter on a diode D, inductor L and capacitor C.

The control circuits of the converters 10, 12, 14 are made in the form of pulse-width modulators input connected to the stabilized voltage buses. The control circuit 10 of the charging Converter 5 is additionally associated with a measuring shunt 8 and load 2 (on-board computer).

The device operates as follows. During operation, the battery 4 operates mainly (98% of the resource) 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 in case of emergencies (loss of orientation of the satellite in the sun) or on 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 the shadow portions of the orbit or in violation of the orientation, the load 2 is powered by the battery 4 through the discharge converter 6.

The battery voltage monitoring device 7 controls the minimum voltage value of the batteries and transmits information about their condition to the load (on-board computer).

The program according to the following algorithm is “embedded” in the on-board computer:

1. If during the discharge of the battery a decrease in the voltage of a battery is detected below the minimum level, on the command of the on-board computer, the charging converter switches to low-charge mode. At the same time, the counting of the reverse polarity capacity (Cp) begins until the end of the discharge (integration of the discharge current in time) of the battery.

2. After the appearance of the excess current of the solar battery (satellite exit from the shadow portion of the orbit), the charging converter is automatically turned on to charge the battery with a small current until the battery has a capacity of at least Cn.

3. After the capacitance battery Cn is informed by the battery, the charging converter, on command from the on-board computer, switches to the normal charge mode.

Thus, the proposed method allows to simplify the technology (by reducing the number of necessary technological operations) of the operation of a nickel-hydrogen storage battery in which individual batteries are reversed during operation.

Claims (1)

A method of operating a nickel-hydrogen storage battery in an autonomous power supply system, which consists in conducting charge-discharge cycles, "bypassing" batteries with a lower capacity, bypass bypass diodes, monitoring the voltage of each battery and charging with small currents to prevent the formation of an explosive concentration of oxygen-hydrogen mixtures, characterized in that they further control the magnitude of the polarity reversal capacity by integrating the discharge current in time of the battery, which The first one reached the minimum voltage value, from the moment this voltage was reached to the end of the discharge, and the polarity reversal capacity is calculated without taking into account the currents through the bypass discharge diodes, and the normal battery charge mode is started after preliminary recharging with a small current with a message of the capacitance of at least the obtained polarity reversal capacitance.