RU2172044C1 - Method for metering capacity of chemical current supplies - Google Patents

Abstract

FIELD: electric measurement technology. SUBSTANCE: method involves metering capacitor charge time in the course of discharge of current supply under check into capacitive load and calculating electric capacity of chemical current supply using formula Q_cl = C•U/(2t_ch•K), where Q_cl is electric capacity of current supply under check, A/h; C is rating of capacitor being charged, F; U is voltage across current supply under check, V; t_ch is charge time of capacitor charged from current supply under check; k is factor including design and technical characteristics of current supply under check. EFFECT: reduced measurement time; facilitated procedure. 1 dwg

Description

 The invention relates to the field of electrical engineering and is intended to measure the residual electrical capacitance of HIT in both stationary and field conditions.

A known method for determining the residual capacity of an acid lead battery (battery) (a.s. N 1619360, H 01 M 10/48, BI N 1, 1991), where the battery is connected to the test load and, measuring the voltage on the battery before connecting load E and with it U _n , calculate the coefficient of the degree of discharge k according to the following formula:
k = (E _max - E) / (U _n - U _min ), (1)
where E _max - maximum battery EMF,
U _min - the minimum allowable voltage on the battery during discharge.

Then, according to a certain early dependence
Q _ost = f (k), (2)
determine the residual capacity of the battery.

The known method has disadvantages. Firstly, it requires large energy costs, because The battery is loaded on a very small load (test) resistance, i.e. if the battery is partially discharged, then after such a check a full discharge is possible, which is unacceptable for the battery, because after such a procedure they cannot be restored. Secondly, the load resistance must be turned on for a very short time, because otherwise, the battery will discharge and the load (test) resistance may fail due to overheating. Thirdly, in the calculation formula (1), the values of E _max and U _min have certain tolerance zones and therefore the calculations according to formulas 1 and 2 cause some uncertainty. And fourthly, as is known [1], the internal resistance of a battery is complex and its magnitude and, accordingly, the internal voltage drop on the battery will depend on the load. Therefore, the value of U _n will also have an indefinite value.

There is also known a pulsed method for measuring the residual capacity of HIT, described in A.S. N 1718305 (H 01 M 10/48, BI N 9, 1992), where the battery is probed with pulses of 10 ^-3 to 10 ³ s in duration depending on the remaining battery capacity, the current is measured against time, and the earlier established dependence is determined residual capacity of HIT. This method is non-operational, because the measurement time can reach 1000 s, i.e., about 17 minutes (for pulse durations of about 10 ³ s). And, in addition, the known method is apparatus-intensive for implementation, since requires the use of special generators with adjustable pulse width and adjustable amplitude.

Closest to the technical nature of the present invention is a method of measuring short circuit resistance (short circuit) HIT described in a. from. N 547878 (H 01 M 10/48, BI N 7, 1977). In the known method, by discharging the test source to a capacitor load, the nanowire voltage change is recorded and a time dependence of this voltage is built, and then, selecting any point on the curve to a voltage value of 0.8 E _hit , the resistance K3 is calculated from the coordinates of this point.

 However, this method is not intended to measure the electric capacitance of the HIT and is rather laborious and long-term, despite the fact that the maximum process time for charging a capacitor is a fraction of a second. In addition, the known method has limitations on the choice of the operating point on the curve (Uc / E ≅ 0.8), which is not always optimal from the point of view of measuring the residual capacity of the HIT.

 The aim of the invention is to reduce the measurement time and simplify the process of measuring the electrical capacitance of HIT.

This goal is achieved by the fact that during the discharge of the test source to the capacitor load, the charge time of the capacitor to the voltage of the source is recorded and the electric capacitance Q _el HIT is calculated by a certain dependence.

 The drawing shows an electrical circuit for measuring the electrical capacitance of a chemical current source.

 The circuit includes a test current source 1, a key 2 for closing a circuit, a capacitor 3 of known capacity, a DC voltmeter 4, a key 5 for opening a circuit and a device 6 for measuring the capacitor charge time (oscilloscope, timer, etc.).

 The connecting wires of the keys 2 and 5 and HIT 1 with the device 6 measuring the charge time of the capacitor are necessary to synchronize the process of measuring time.

 The resistance of the connecting wires, key 2 in the closed state and current collectors should be as low as possible (about an order of magnitude less than the internal resistance of the measured current source).

The electric capacitance Q _{el of the} measured current source can be represented as the sum of the nth number of identical small capacities and written as follows:
Q _el = n • Q _k + Q _ost , (3)
where Q _k is the amount of electricity accumulated by the capacitor during its charge or the electric capacity of the storage capacitor;
n is a positive integer;
Q _ost - the remaining part of the electric capacitance of the measured current source, and Q _ost <Q _k .

When the values of Q _el >> Q _{k the} value of Q _ost can be neglected and then the formula (3) can be written in the form:
Q _el = n • Q _k . (4)
The value of the capacitance Q _k is determined, as is known [2], by the following expression:
Q _k = C • U / 2, (5)
where C is the Faraday capacitance of the capacitor;
U is the voltage at the measured current source.

Based on formulas (4) and (5), we write:
Q _el = n • C • U / 2, (6)
where Q _el - [C] or [A • c];
C - [A • c / B];
U - [B].

Since the electric capacitance Q _el HIT is usually expressed in A • h, then expression (6) can be written in the following form:
Q _el • 3600 = n • Q _k = n • C • U / 2. (7)
Then from the expression (7) we get:
n = 3600 • 2 • Q _e / (C • U) (8)
or
n = 3600 - Q _el / Q _k . (9)
Let us determine the number n for CIT with an electric capacity Q _el1 = 55 A • h (U = 12 V) and Q _el2 = 38 mA • h (U = 1.5 V) when they are discharged to a capacitor having a capacitance C = 5000 μF. Then, according to f-le (5), we have:
Q _k1 = 0.005 • 12/2 = 0.03 [A • c].

Q _k2 = 0.005 • 1.5 / 2 = 0.00375 [A • c].

By the formula (9), we calculate the number n for each of the given values of HIT:
n1 = 55 • 3600 / 0.03 = 6600000,
n2 = 0.038 • 3600 / 0.00375 = 36480.

 That is, such a number of samples can be made continuously for each of the given CITs using a capacitor of known capacitance (for example, 5000 μF) in order to completely discharge them.

Then, the number of possible charges of the storage capacitor or continuous samples of the charge N from the studied CIT per unit time (for 1 s) is defined as:
N = 3600 • Q _el / (3600 • Q _k ) = Q _el / Q _k , (10)
and for HIT of known capacity we get:
N1 = 55 / 0.03 = 1833.3;
N2 = 0.038 / 0.00375 = 10.13.

That is, such a number of samples can be made for each of the given CITs using a capacitor of known capacitance (5000 μF) per unit time t _unit = 1 s.

If we know the number of possible continuous charge samples for specific CIT per unit time, then we can also determine the charge time of the capacitor per sample taking into account the electric capacity of the CIT, i.e.:
t _zar = t _u / N, [c] (11)
or, given (10), we obtain:
t _zar = t _u / N = t _u / Q _el / Q _k = t _u • C • U / 2Q _el [s / (A • h) / (A • h)]. (12)
As the studies and practical measurements showed, the number N is indeed a value inversely proportional to the charge time t _{zar of the} storage capacitor, and then, based on (12), we write:
Q _el = t _u / t _zar = t _u • C • U / 2t _zar , [A • h], (13)
or, for simplification, omitting the unit of time t _u and taking it into account only in dimension, we write:
Q _el = Q _k / t _zar = C • U / 2t _zar , [A • h]. (13a)
When measuring Q _{el, the} determination of the total charge time of the storage capacitor due to the exponential nature of the charging curve at its final stage is associated with large measurement errors. Therefore, from the point of view of reducing the measurement error, it is convenient to measure the capacitor charge time not to the full value of the HIT voltage, but to a certain level of it, for example, 0.95 U _hit or 0.9U _hit . The following levels were practically tested: 0.95; 0.9; 0.86; 0.8; 0.7; 0.63; 0.5. The best results were obtained at levels from 0.95 to 0.86, because at these levels, all active electrode surfaces are included in the CES. Therefore, for practical calculations, formula (13a) will have the following form:
Q _el = C • U / (2t _charge • k), [A • h], (14)
where k is the coefficient set for each type of HIT, because it is determined by the materials used in the manufacture of current sources, its design and technological parameters, as well as the charge level of the storage capacitor (for miniature cells and acidic leaky batteries with a charge level of 0.95 U _hit k = 2).

Based on the foregoing, we determine the theoretical charge time of the storage capacitor for a known electrical capacity of a chemical current source:
t _zar = C • U • / (2Q _el • k), [c] (15)
or
t _zar = Q _k / (Q _el • k), [c]. (16)
From formulas (15) and (16), for Q _el1 = 55 A • h and Q _el2 = 38 mA • h we get:
t _zar1 = 1 / (1833.33 • 2) = 0.000272727 with ≈ 273 μs,
t _zar2 = 1 / (10.13 • 2) = 0.049358341 s ≈ 49.35 ms.

 Thus, knowing the value of k for each type of CIT, it is possible to calculate in advance (theoretically) the charge time of a capacitor of known capacity and, by its deviation in one direction or another, determine the degree of charge or residual capacity of the studied CIT.

 To confirm the above, the results of the measurements are presented below. A batch of six miniature batteries (A76 LR44) of Chinese manufacture using Japanese technology with a nominal voltage of 1.5 V and an electric capacity of 50 mA • h had the measurement results presented in table. 1.

 In the table. 2 shows the results of measurements of various types of ChIT.

In the table. 3 shows the comparative technical and economic indicators of elements of type AG8 of different manufacturers:
Sources of information
1. A.E. Zorokhovich et al. "Devices for charging and discharging batteries", M .: "Energy", 1975, 208 S.

 2. A. M. Vailov and F.I. Eigel "Automation of control and maintenance of batteries", M., "Communication", 1975, p. 4-87.

 3. V.V. Romanov, Yu.M. Khashev "Chemical sources of current", M .: "Soviet radio", 1978, 264 p.

 4. V. S. Bagotsky, A. M. Skundin "Chemical current sources", M.: "Energoizdat", 1981, 360 pp.

Claims (1)

A method for measuring the electrical capacitance of chemical current sources by measuring the voltage at the source, discharging it to the capacitor load and calculating the measured parameter, characterized in that during the discharge of the test source to the capacitor load, the charge time of the capacitor is measured and the electric capacitance of the measured chemical current source is calculated by the formula
Q _el = C • U / (2t _zar • k),
where Q _el - electric capacitance of the measured current source, A • h;
C is the capacitance of a charged capacitor, f;
U is the voltage at the measured current source, V;
t _zar — time of the capacitor charge from the measured current source, s;
k is a coefficient taking into account the structural and technological features of the measured chemical current source.

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