RU2201642C2 - Device for measuring storage battery degree of charge - Google Patents

Abstract

FIELD: measuring residual capacity of lead storage battery. SUBSTANCE: device has series- connected voltage-to-frequency converter, frequency divider, binary-decimal counter, and digital display, as well as current-measuring and ballast resistors and input leads for connecting storage battery. In addition device is provided with switching and controlling members, charge current regulator, null device, logic adder, and matching amplifier. Positive input lead is coupled through series-connected switching and control members, ballast and currentmeasuring resistors with negative input lead for storage battery connection. Switching member output is coupled with first input of null device whose second input is connected to first reference-voltage supply; null-device output is connected to first input of logic adder whose second input is coupled with control-signal source. Logic adder output is connected to control input of switching member. In addition output of matching amplifier is coupled with third input of null device, voltage-to-frequency converter input, and second input of discharge current regulator whose first input is connected to control input of control member, matching amplifier input being connected to negative input lead. EFFECT: enhanced reliability of measurement results, improved safety of storage battery during measurement procedures. 1 dwg

Description

 The invention relates to a device for measuring the residual capacity of a lead battery.

 A device for measuring the charge of a battery containing input terminals for connecting a battery, a temperature sensor for installation in a battery, a current sensor connected in series with input terminals and connected to an amplifier, a pulse generator, a conversion unit programmed with a series of graphs that reflect the dependence of the ampere-hour battery return as a function of discharge current and temperature, conversion units, controlled keys, two amplifiers, a functional amplifier, a rectifier and automatic cue attenuator (see. AS USSR 1339695, cl. H 01 M 10/48, G 01 R 31/36, 1987 YG).

 The disadvantage of this device is the structural complexity.

 There is also known a device for measuring the charge of a battery containing a voltage to frequency converter, a frequency divider, a binary-decimal counter, a digital indicator connected in series, as well as current-measuring and ballast resistors and input leads for connecting the battery (see Evseev A. Useful schemes for radio amateurs. Issue 2-M. "Solon-R", 1999, p. 188-196).

 In this device, in the discharge mode, the battery is connected to a ballast resistor, while the voltage from the current-measuring resistor, proportional to the discharge current, is fed to the input of the voltage converter to the frequency. The voltage pulses from the output of this converter through the frequency divider are fed to the input of the binary-decimal counter, the output of which is connected to a seven-segment indicator.

 Thus, with appropriate scaling, the indicator will display in ampere-hours the amount of electricity that the battery has given up in discharge mode at this point in time.

 This device has the following disadvantages.

 The moment of the end of the battery discharge is determined by the moment when the voltage at its terminals reaches a certain minimum value, which depends on the discharge mode and is regulated by GOST 959-91 "Lead-acid rechargeable starter batteries with a voltage of 12 V for automotive and motorcycle equipment" and the typical Instructions for the operation of the EIC. 563410.001 IE "Lead starter batteries with a capacity of over 30 A • h". So, for example, in the 10-hour discharge mode, the minimum allowable voltage is (for a 12-volt battery) 10.2 + 0.05 V.

 The prototype device does not have special elements and the necessary connections to ensure automatic shutdown of the battery discharge mode, while lowering the voltage at its terminals below the specified minimum level leads to sulfation, irreversible changes and deterioration in the quality characteristics of the battery.

 The second disadvantage of the prototype device is that the magnitude of the discharge current changes as the battery voltage decreases during the discharge. However, these documents require that when measuring the battery capacity to maintain the discharge current unchanged. Failure to do so changes the electrical processes in the battery during discharge and reduces the reliability of the measurement results.

 The problem to which the claimed solution is directed is expressed in increasing the reliability of the measurement results and eliminating the possibility of battery damage during measurement work.

 The technical result achieved by solving the problem is expressed in providing the possibility of "measurements" at a constant value of the discharge current and ensuring automatic shutdown of the device when the voltage at the battery terminals is lower than the minimum level acceptable under the conditions of its operation.

 To solve this problem, a device for measuring the charge of a battery containing a voltage to frequency converter, a frequency divider, a binary-decimal counter, a digital indicator connected in series, as well as current-measuring and ballast resistors and input terminals for connecting the battery, is characterized in that it is additionally equipped with switching and regulating elements, a discharge current regulator, a zero-organ, a logic adder, a matching amplifier, while the input an integral output through series-connected switching and regulating elements, ballast and current-measuring resistors is connected to a negative input terminal for connecting the battery, in addition, the output of the switching element is connected to the first input of the zero-organ, the second input of which is connected to the first reference voltage source, while the output zero-organ is connected to the first input of the logical adder, the second input of which is connected to the source of the control signal, and the output of the logical adder is connected to with the input of the switching element, in addition, the output of the matching amplifier is connected to the third input of the zero-organ, the input of the voltage to frequency converter and the second input of the discharge current regulator, the first input of which is connected to the second source of the reference voltage, while the output of the current regulator is connected to the control input of the regulating element, and the input of the matching amplifier is connected to the input negative terminal.

 A comparative analysis of the features of the claimed solution with the signs of the prototype and analogues indicates the compliance of the claimed solution with the criterion of "novelty."

 The essential features that are distinctive from the prototype satisfy the requirement of an inventive step, and their combination indicates a causal relationship aimed at achieving a technical result that provides a solution to the problem.

 The drawing shows a functional diagram of the device.

 The drawing shows a voltage to frequency converter 1, a frequency divider 2, a binary decimal counter 3, a digital indicator 4, a current measuring resistor 5, a ballast resistor 6, a switching element 7, a discharge current regulator 8, a regulating element 9, a null-organ 10, a logical adder 11 and matching amplifier 12.

 As a voltage to frequency converter 1, a standard specialized microcircuit, for example, KR 1108PP1, can be used. As a frequency divider 2 and a binary decimal counter 3, well-known circuit solutions based on microcircuits operating in binary counter mode can be used. Digital indicator 4, current-measuring 5 and ballast 6 resistors are known technical solutions, the specific choice of which is determined by the operating parameters of the device. As a switching element 7, a relay of known design with a make contact can be used. As a regulator 8 of the discharge current, an adder connected in such a way that the input signal and the feedback signal for the discharge current, with opposite signs, can come to its input. As the regulating element 9 can be used transistor. As a null organ 10, an operational amplifier included in the comparator circuit can be used. As a logical adder 11, a logical OR scheme may be used. As a matching amplifier 12, an operational amplifier in a scaled signal conversion mode can be used.

 As the first and second sources of the reference voltage 13 and 15, zener diodes of known types can be used.

 As the source of the control signal 14, a variable resistor included in the potentiometer circuit can be used.

The discharge current of the battery, which is connected to the terminals (+) and (-), passes through a series-connected switching element 7, a regulating element 9, a ballast resistor 6 and a current-measuring resistor 5. The output of the switching element 7 is connected to the first input of the zero-organ 10, the second input of which receives the reference voltage U _1, (from the first reference voltage source 13) corresponding to the minimum battery voltage at which the discharge mode disconnection must occur, and the third input zero-body coupled to the output read out amplifier 12. The output zero-body 10 is connected to a first input of the adder logic 11, and at its second input receives the signal U ₂ (from the control signal source 14) to activate the device in a discharge mode. The output of the logical adder 11 is connected to the control input of the switching element 7. The input of the regulatory element 9 is connected to the output of the controller 8, the first input of which receives the reference voltage U ₃ (from the second source of the reference voltage 15), proportional to the specified value of the cut current, and to its second input is a feedback signal on the discharge current from the output of the matching amplifier 12, the input of which is connected to a current-measuring resistor 5. The signal from the output of the amplifier 12 also arrives at the input of the voltage converter 1 to the frequency. The output of the converter 1 through a series-connected frequency divider 2 and a binary-decimal counter 3 is connected to the input of a digital indicator 4, and the input of the measuring device 13 is connected to a current-measuring resistor 5.

 The device operates as follows.

To enable the device in discharge mode, a control voltage pulse U ₂ is applied to the first input of element 11, which, through this element, acts on the control input of switching element 7 and puts the latter into the on state. The battery is connected to the discharge, and the magnitude of the discharge current depends on the value of the reference voltage U ₃ and is maintained constant during the entire discharge mode.

 A voltage proportional to the magnitude of the discharge current from the output of the amplifier 12 is fed to the input of the voltage converter 1 to the frequency, and pulses are generated at the output of the latter, the number of which per unit time is proportional to the product of the discharge current by the time, i.e. amp hours. These voltage pulses through the frequency divider 2 and binary-decimal counter 3 are fed to digital indicator 4. With appropriate scaling, indicator 4 will display the number of ampere-hours given by the battery since the device was turned on.

 When the voltage at the battery terminals is reduced to a predetermined minimum value, the zero-organ 10 is triggered and, through the logic adder 11, turns off the switching element 7 and, accordingly, the discharge mode is turned off.

 In this case, the number of ampere-hours given by the battery in the discharge mode will be initiated on the digital indicator 4.

 The voltage from the output of the amplifier 12, proportional to the magnitude of the discharge current and supplied to the third input of the zero-organ, compensates for the voltage drop across the connecting wires that connect the device to the terminals of the battery.

Claims (1)

 A device for measuring the charge of a battery containing a voltage to frequency converter, a frequency divider, a binary-decimal counter, a digital indicator connected in series, as well as current-measuring and ballast resistors and input leads for connecting the battery, characterized in that it is additionally equipped with a switching and regulating elements, discharge current regulator, zero-organ, logic adder, matching amplifier, while the input is positive through sequentially switching and regulating elements, ballast and current-measuring resistors are connected to the negative input terminal for connecting the battery, in addition, the output of the switching element is connected to the first input of the zero-organ, the second input of which is connected to the first source of the reference voltage, while the output of the zero-organ connected to the first input of the logical adder, the second input of which is connected to the source of the control signal, and the output of the logical adder is connected to the control input of the switching about the element, in addition, the output of the matching amplifier is connected to the third input of the zero-organ, the input of the voltage converter to the frequency and the second input of the discharge current regulator, the first input of which is connected to the second source of the reference voltage, while the output of the current regulator is connected to the control input of the regulating element and the input of the matching amplifier is connected to the input negative terminal.