SU1755351A1 - Method and device for control of solar battery characteristics - Google Patents

Abstract

The invention relates to the electrical industry and can be used in power supply systems for space objects. Monitoring the characteristics of a solar battery is based on determining the characteristics of an additional solar battery that operates under equivalent conditions, like the main battery. 2 sec. and 1 z.p. f-ly, 1 ill.

Description

The invention relates to the field of electrical engineering, in particular, to methods and devices of DC power supply systems widely used in space objects and other parts of the national economy.

There are known methods for controlling the characteristics of a solar battery, given in the book by G. Rauschenbach, Handbook for Designing Solar Cells, M., Energo-Atomizdat, 1983, p. 338 1, in which the characteristics are monitored from field tests of experimental solar cells and directly during operation large batteries on satellites.

Methods for measuring the current-voltage characteristics of solar cells are also known (see p. 238 1J, in which the parameters are measured either by the light-voltage characteristic or by the diode (tempo) characteristic.

The characteristics of solar cells in orbit and the degree of degradation of their parameters are necessary to determine the effect on these characteristics of the design features of the satellites, the study of degradation

losses due to space conditions.

At the same time, under normal operating conditions, where the solar battery is constantly loaded, i.e., it provides consumers with energy, systematic monitoring of the energy balance is required, as determined by the results of measuring solar cell parameters.

In the practice of operating space objects, telemetric monitoring of parameters is carried out: current of the solar battery STBS), load current (TN), voltage at the load (LV), voltage of the solar battery (NBS). The evaluation of the energy balance according to the TM-control data is carried out on the basis of the following expression

 „,

where bs is the current of the solar battery;

n is the load current;

k is a coefficient numerically equal to the efficiency of the power supply system.

If this ratio is not fulfilled, it is necessary either to connect additional sections of the solar battery or to reduce the load by limiting the number of working service equipment.

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However, this method of controlling the energy balance has a large error (up to 70%), due to the nonlinear dependence of the change in the volt-ampere characteristic of the solar battery (see, p. 25 1).

The negativeness of the method of controlling the energy balance is aggravated in a system that has a serial voltage regulator on the load, since the sequential voltage regulator feature is the functional dependence of the solar battery power at its input on the required load power at the output. The closest to the proposed technical entity is a method implemented in a power supply device using solar cells, as set forth in Japanese Application No. 62-52541 2. The solution has an auxiliary solar cell for determining the short circuit current of the main solar cell.

However, the non-equivalent and non-linear nature of the change in the short-circuit current does not allow unambiguously to control the power supply system due to the inadequacy of degradation losses under the conditions of outer space of the main and auxiliary solar cells, due to different operating conditions. The fact is that the short-circuit (or idle) operation of the auxiliary solar battery mainly results in a difference in their temperature conditions, which will be determined by the difference in the energy perceived from the Sun and withdrawn from it by transmission to the load. At the same time, if the additional solar battery works in the short-circuit or idling mode, then the power output in this way is zero. Therefore, the temperature of the additional solar battery will be higher than that of the main one, and this, as is well known, affects the current value of its parameters and their resource changes.

The closest to the proposed device is an autonomous power supply system (see USSR author's certificate No. 1519498, class H 02 J 7/35, 1986 3) containing a partitioned solar battery connected through a transistor voltage regulator and filter to the terminals loads, capacitor, first and second pulse generators with a frequency proportional to the supply voltage, the outputs of which are connected to the transistor controller. In this case, the first generator is connected to the solar battery, and

the second generator is to its additional section. The additional section of the solar battery is idling and is in the same operating conditions (vacuum, radiation, illumination) as the main battery.

The autonomous power supply system 3 provides an increase in the efficiency of use of the solar battery by maintaining a voltage value equal to the voltage on the additional section of the solar battery corresponding to its maximum power.

However, determining the short-circuit current or the no-load voltage using an auxiliary or additional solar cell does not take into account the inequivalence of degradation levels of solar cell parameters operating in different operating modes, as well as the characteristics of orbital conditions, for example, when their illumination changes due to -, battery tation on the Sun, passage of shadow areas, shading by structural elements.

The need to ensure the position of the working point on the IVC of an additional BS, corresponding to the working point B AX of the main BS, is also determined by the following circumstances. According to literary data, for example, from fig. 2 articles Flight characteristics of solar batteries installed on remote panels and on the body of the CTS satellite (see the abstract collection of articles Direct Conversion of Thermal and Chemical Energy to Electric Energy No. 25, 1978) show that for approximately 260 over-exploitation idle voltage decreased, the current of which closure is 4%, 5%, and the maximum power of the BS decreased by 8%, and the nature of the resource reduction Ohx, kz, Pmax is different. The article Biennial experimental studies of solar cells onboard the ATS-B satellite (see abstract collection of articles Direct Conversion of Thermal and Chemical Energy into Electricity No. 5, 1979, p.11) shows that after two years of operation of a BS in geostationary orbit decreased by (12.7-19.4)%, Uxx decreased by (1.1-4.2)%, Pmax -na (13.7-24.4)%, i.e. the rate and nature of the decrease in these parameters also are different. This is explained by the different influence of space factors on the equivalent circuit of a photoconverter.

In conjunction with this, it is also known from practice that the degradation of the current – voltage characteristics of a BS depends significantly on the electric mode.

its operation as part of the spacecraft. In accordance with the article in the Newsletter, Direct Conversion of Different Kinds of Energy into Electricity No. 5 (145), M, 1988, p. 65. this leads to a difference) in the rates of degradation of an additional BS and the main BS and, as a consequence, an accumulation of errors in determining the BS power and the spacecraft’s energy capabilities. So from the formula (5) of this article, it follows that the constant degradation of BS depends on

К Кр + Кп X ,,

where K is the BS degradation constant;

Kp, Kp are silicon degradation constants of p and p types, respectively;

X is variable depending on the operating conditions.

Also, from the formula specified in paragraph 4 of the conclusions of this article, the variable X depends, inter alia, on 1) region — the voltage of the working point of the photoconverter. When 11bl changes from 0.1 V (practically short circuit mode) to 0b 0.6 volts (idle mode), the value of X changes tenfold, i.e. in the short circuit mode, the BS degradation rate is much lower than XX mode, and therefore not equivalent to the mode of the main BS under load.

The purpose of the invention is to expand the functionality and improve the accuracy of the method of monitoring the characteristics of the solar battery and increase the reliability of the device for carrying out the proposed method.

The goal is achieved by measuring the current of an additional solar battery at a voltage close to the voltage at the load, and the current of the main solar battery is determined by the formula

from the axis I DOS. additional OBS

BSB ° ZBSDOP

where BSAOP is the current of the additional solar battery;

5ССОСН - area of the main solar battery;

5BSA ° P - area of additional solar batteries.

An increase in the reliability of the device is achieved by additionally introducing a resistor that shunts an additional solar battery and a threshold voltage monitoring device connected by input to an additional solar battery and output to a load, the additional solar battery being designed as n-sections electrically connected in parallel. and posted on

opposite parts of the solar panel design.

The drawing shows a schematic diagram of the device.

The device (Fig. 1) # containing the main 1 and additional 2 solar batteries, the main one being connected to load 3 via a serial converter 4, a battery 5 connected via a charge converter 6 to the main solar battery, and through a discharge converter 7 to the load, additionally introduced resistor 8, shunting additional solar

5, the battery, and the threshold voltage control device 9, the input connected to an additional solar battery, and the output to the load. Moreover, the additional solar battery is made in the form of n-sections, connected electrically by a parasite: and placed on opposite parts of the solar battery design.

The device works as follows.

5 The additional solar battery 2 is loaded with a resistor 8 and generates a voltage close to the voltage of load 3. This, according to the operating conditions (temperature, degradation, shading), corresponds to the operating mode of the main battery 1. With sufficient illumination, 1360 ± 40W / m (AMO conditions) the additional solar battery 2 is in stationary mode of operation. Current passing

5 through a resistor 8, can be used to estimate the disposable current of the main solar battery 1. A threshold voltage monitoring device 9 at a voltage level close to the voltage at load 3,

0 does not generate a signal to disconnect part of the load or to connect back-up solar cell sections. In the case of a decrease in the power of the solar luminous flux, for example, as a result of abnormal operation

5 orientation systems, the power of the luminous flux acting on the solar panels 1 and 2, falls. At the same time, the power generated by solar batteries 1 and 2 is reduced. Battery 5 is activated and, through discharge converter 7, compensates for the lack of power from solar battery 1 at load 3. During this process, voltage and current are also reduced

5 by the solar battery 2 and when the predetermined level is reached, the threshold device 9 generates a signal for disconnecting the session load 9. As a result, the spacecraft is transferred to the spin mode, which provides the cyclic tracking of the solar batteries 1 and 2 to the Sun. Thus, a positive energy balance is created in the emergency power mode and, as a result, the capacity consumed from the rechargeable battery 5 is limited. Before the planned shading of the solar batteries (passing the shadow sections of the Earth, the Moon), the threshold device 9 is blocked by radio commands or time stamps,

To increase reliability, it is very rational to make an additional solar battery in the form of p-sections, connected electrically in parallel. This allows sampling, for example, from two any of the three available sections. Along with this, the sections of the additional solar battery 2 are expediently placed on opposite parts of the solar battery 1 design. This feature will make it possible to free them from their shadowing by the structural elements of the spacecraft, which also increases the reliability of the power supply system.

On page 236 1, the characteristic effect of the load (resistor) on the operating point of the current-voltage characteristic of the control (additional) solar cell is shown. For specific conditions, the value of resistor 8 (Fig. 1) is selected based on the voltage on the additional solar battery 2, close to the voltage of the load 3. As a result, the characteristic U f (l) has a wide range of voltage and current variations due to illumination, equivalent in temperature and degradation losses, which will allow The control of current and voltage parameters is the following: to generate a signal for load shedding, for example, at a given voltage level as a result of a decrease in the illumination intensity of solar cells due to factors such as loss of orientation to the Sun, shading of structural elements, etc. ; determine the disposable current of the main solar battery according to the proposed formula,

Indeed, if the main and additional batteries are equivalent in form to the current – voltage characteristics and operating conditions, their characteristics will be proportional to the ratio of areas. Thanks to these parameters, the additional solar battery (current and voltage) expands the functionality of the power supply systems and increases the accuracy of the control of the energy balance, simplifying the procedure for analyzing it.

Claims (3)

1. A method for controlling the characteristics of a solar battery by measuring parameters of an additional solar battery, characterized in that the purpose of extending the functionality and increasing the accuracy, the current of the additional solar battery is measured at a voltage close to the voltage on the load, and the current main solar cell is carried out according to the formula 8bss BS axes BS Chipboard StarShop Where is the current of the additional solar battery; ZBSOSN - the area of the main solar battery; ZPSDOP is the area of the additional solar battery. 2. A device for monitoring the characteristics of the solar battery containing the main and additional solar cells, while the main one is connected to load through a serial converter, a battery connected via a charge converter to the main solar battery, and through a discharge converter to a load, which is due to the fact that, in order to increase reliability, a resistor is added that shunts an additional solar battery and a threshold a voltage control device, the input connected to an additional solar battery, and the output to the load. 3. The device according to claim 2, which is designed so that the additional solar battery is made in the form of n sections, connected electrically in parallel and placed on opposite parts of the solar battery design.