RU2325015C1 - Automatic device for accelerated asymmetric battery charge - Google Patents

Abstract

FIELD: electrical engineering; battery charging.

SUBSTANCE: after accumulator battery (AB) is connected to charger type of battery is selected automatically. According to selected AB type charging starts by specified procedure corresponding to AB type. Device contains control circuit as per specified procedure and control circuit of power force component. Control of power component is performed by means of single-chip microprocessor. Charging and discharging current is generated by means of high-frequency power-width modulation (PWM) inverter. Charging and discharging current is stabilized due to current feedback. Voltage and shunt pickup signals are supplied to single-chip microprocessor to provide charging process control.

EFFECT: reduction of weight, dimensions, price of device and improved efficiency.

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Description

The invention relates to electrical engineering, and in particular to chargers used to charge batteries (AB) with an asymmetric current.

A device [1] is known for charging batteries with an asymmetric current. This device is built on the principle of PWM converters to form an asymmetric current. In this device, the discharge pulse follows the charging pulse with a pause between them. The device includes a control circuit according to a predetermined algorithm (CPSA) and a power unit control circuit (CMS). The control unit includes an indication unit, an audible alarm unit, a single-chip microprocessor (OMP), a current sensor unit, and a voltage sensor unit. The control system includes two filter units, two amplifier units, a charge current source control unit (for generating a charge pulse), a discharge current source control unit (for generating a discharge pulse), and a load cell unit. In the process of charge, the amplitudes of the charging and discharge current do not change. This is achieved by current feedback. In the current sensor block, the captured signal is amplified, inverted (in the case of a reverse pulse) using auxiliary elements, and fed to the input of a single-chip microprocessor. Depending on the signal received from the current sensor, the microprocessor with the help of pulse width modulation (PWM) supports stabilization of the charging or discharge current.

The disadvantages of this device are: the presence of a block of the load element, separate blocks for generating charging and discharge pulses, a current sensor block for inverting and amplifying the signal supplied to the OMP to stabilize the current, and an additional diode, which leads to an increase in mass, dimensions, cost of the product and reduction of efficiency due to losses in these blocks.

A device [2] is known for charging batteries with an asymmetric current, made on the basis of a single-chip microprocessor. The device is based on PWM converters and is used to charge sealed batteries. In the process of charging, the device generates stabilized charging and discharge pulses that follow one after another. The end of the charge occurs upon reaching the maximum voltage or by changing the sign of the first derivative with respect to voltage. The device includes a control circuit according to a predetermined algorithm (CPSA) and a power unit control circuit (CMS). The control system includes an indication unit, an audible alarm unit, a single-chip microprocessor, a current sensor unit, a voltage sensor unit, and a power supply. The control system includes two filter units, two amplifier units, a charge current source control unit (for generating a charge pulse), a discharge current source control unit (for generating a discharge pulse), a battery connection unit, two diodes. In this device, energy recovery is introduced, the discharge pulse is converted into a capacitor charge in the filter unit and is used to create a charging pulse.

The disadvantages of this device are the presence of two blocks for the formation of charging and discharge pulses, a current sensor block for inverting and amplifying the signal supplied to the OMP to stabilize the current, and an additional diode, which leads to an increase in mass, dimensions, cost of the product and lower efficiency due to losses in these blocks.

The objective of the invention is to simplify the control circuit of the power unit and the control circuit according to a predetermined algorithm, reduce losses, reduce the mass and dimensions of the device by combining the functions performed by individual blocks

This object is achieved in that in the known device [2] for accelerated charge with an asymmetric current AB, containing a control circuit of the power unit, including two filter units, an amplifier unit, a diode, the cathode of which is connected to one of the inputs of the filter unit, the battery connection unit with terminals for connection, and a control circuit according to a predetermined algorithm, including a power supply, the positive contact of which is connected to the anode of the diode, and zero contact with the second input of the filter unit included in the system is controlled a power unit, a voltage sensor unit, an audible alarm unit, an indication unit connected to a single-chip microprocessor unit and combined in a single-chip microprocessor unit, a charge algorithm setting unit, a charge mode setting unit, a pulse-width modulation unit, connected to the control unit, in a power-part control circuit has been introduced a charge-discharge current generating unit, the input of which is connected to the filter unit, and the output to the battery unit and to the input of the filter unit, the output of which is connected with a zero contact of the power supply, and in the control circuit according to the specified algorithm, the amplification and differential analog-to-digital converter (ADC) units included in the OMP, and a shunt, one output of which is connected to the zero contact of the power supply, and the second to the battery batteries and an amplification unit connected to the differential ADC unit performing the function of inverting the signal, the second input of the differential ADC is connected to the output of the voltage sensor, and the output from the differential ADC is connected to the corresponding th input of the control unit, the signal from which is fed to the PWM unit, an output connected to the input of amplifier block connected to the block formation of the charge-discharge current control circuit power part.

The single-chip microprocessor contains a PWM unit designed to control pulse-width modulation at a high frequency to form charging and discharge currents, a differential ADC unit for reading the positive and negative signal from the shunt through the amplification unit, a charge mode setting unit, a task unit charge algorithm, control unit, program and data memory.

The drawing shows a block diagram of this device.

The device includes a control circuit according to a given algorithm 1 and a power part 2 control circuit. A single-chip microprocessor 3 unit consisting of a PWM block 4, a charge mode setting unit 5, a differential ADC unit 6, an amplification unit 7, a charge algorithm setting unit 8, and a control unit 9 connected to the sound alarm unit 10, the indication unit 11, the voltage sensor unit 12 is connected to the differential ADC unit 6 and the battery connection unit 13, the output of the shunt 14 is connected to the amplification unit 7, the battery connection unit ornyh batteries 13 and neutral wire power supply. The output of the PWM unit 4 is connected to the input of the amplifier unit 15, the output of which is connected to the input of the charge-discharge current generating unit 16, the battery connection unit 13 is connected to the charge mode setting unit 5. The supply voltage is supplied to the power supply 17, the positive output of the supply voltage is connected with the anode of the diode 18, the cathode of which is connected to the input of the filter unit 19. The output of the filter unit 19 is connected to the input of the charge-discharge current generating unit 16, the output of which is connected to the battery connection unit 13 and bl com filter 20, a second terminal connected to the neutral conductor. The input of the battery connection unit 13 is connected to the battery unit 21 AB.

The device operates as follows. When the device is turned on, the supply voltage is supplied to the power supply unit 17, which generates constant stabilized voltages to power the unit of a single-chip microprocessor 3, an indication unit 11, an audible alarm unit 10, a battery connection unit 13, an amplifier unit 15. Through a filter unit 19 and a diode 18, the supply the voltage is supplied to the input of the control unit of the source of charge-discharge current 16. OMP 3 in accordance with a predetermined algorithm generates a signal to lock the amplifier unit 15 in order to avoid opening ovyh keys. After connecting AB 21 to the battery connection unit 13, the charge mode setting unit 5 automatically selects the charge mode corresponding to this type of battery. The input of the differential ADC 6 from the voltage sensor unit 12 receives voltage from the battery. In accordance with the selected charge mode, the charge algorithm task unit 8 through the control unit 9 and the PWM unit 4 provides signals to the amplifier unit 15 and then to the charge-discharge current generating unit 16, which sets the amplitudes and durations of the charging and discharge currents. To display the selected charge mode, the single-chip microprocessor 3 gives a signal to the display unit 11, where the LED that this mode corresponds to is lit. The amplitudes of the charging and discharge currents are controlled using a signal read from shunt (R) 14 and fed to the differential ADC unit 6 through the amplification unit 7. When the charging current is generated, the single-chip microprocessor 3 through the PWM unit 4 and the amplifier unit 15 provides signals to the charge forming unit -discharge current 16 with a high frequency and corresponding duration, at which the current passes from the power supply 17 to the battery 21. When generating the discharge current, the single-chip microprocessor 3 through the PWM 4 and the amplifier block 15 p sends signals to the block forming the charge-discharge current 16 with the same frequency, but with a different duration, at which the current flows in a different direction. In this case, the battery 21 is a discharge pulse power source. The signal from the shunt (R) 14 is fed to the amplification unit of a single-chip microprocessor 3 and then to the differential inputs of the ADC 6 to stabilize the charging and discharge current. In accordance with the polarity of the signal arriving at the differential ADC block 6 from the shunt (R) 14 through the amplification block 7, the necessary bits are set in software (in accordance with the algorithm) in a single-chip microprocessor 3 for reading a positive or negative signal. During the charge, in accordance with the algorithm, the voltage at AB 21 is monitored. At the end of the charging process, the single-chip microprocessor 3 stops supplying signals to the amplifier unit 15 and a blocking level is set at the input of the charge-discharge current generating unit 16, the single-chip microprocessor 3 gives a signal that the process is completed charge to the sound alarm unit 10 and the display unit 11.

The charge and discharge current circuit consists of a charge-discharge current generating unit 16, which is controlled by a single-chip microprocessor 3 through an amplifier unit 15. The charge-discharge current generating unit is a high-frequency converter. When forming a charging current, it works as a step-down stabilizer, and when forming a negative current, it works as a step-up stabilizer. As a result of such a circuitry solution, it is possible to use one block to form both positive and negative pulses. The diode 18 protects the power source 17 from surges during a discharge current pulse. The filter unit 19 protects the supply voltage from low-frequency and high-frequency interference that occurs when switching in the control unit of the source of charge-discharge current 16. When generating a discharge pulse, part of the energy is recovered in the capacitor located in the filter unit 19, which is then used to form a charge pulse. Such a construction of the power unit allows, with minimal losses, to return the energy of the discharge pulse to the battery.

The device is designed for accelerated charging of sealed batteries with voltage from 4.8 to 12.0 V in the range of supply voltage from 20 to 30 V.

The combination of the control unit of the charging current source and the control unit of the discharge current source in the charge-discharge current generation unit in the control system and the introduction of the amplification unit and the replacement of the ADC unit with the differential ADC unit in the control and control system made it possible to reduce the losses, weight, dimensions and cost of the device.

Information sources

1. Copyright certificate No. 2215353.

2. Copyright certificate No. 2216087.

Claims (1)

An automated device for accelerated charging of a battery with an asymmetric current, comprising a power unit control circuit including a filter unit 19, a filter unit 20, an amplifier unit, a diode whose cathode is connected to one of the inputs of the filter unit 19, a battery connection unit with terminals for connection, and a control circuit according to a predetermined algorithm, including a power supply unit, the positive contact of which is connected to the anode of the diode, and zero contact with the second input of the filter unit 19 included in the control circuit power unit, voltage sensor unit, audible alarm unit, display unit connected to a single-chip microprocessor (OMP) unit and combined in a single-chip microprocessor unit, a charge algorithm setting unit, a charge mode setting unit, a pulse-width modulation (PWM) unit, connected with a control unit, characterized in that a charge-discharge current generating unit is introduced into the power part control circuit, the input of which is connected to the filter unit 19, and the output to the battery unit and to the input of the unit filters 20, the output of which is connected to the zero contact of the power supply, the control circuit according to the specified algorithm includes the amplification units and a differential analog-to-digital converter (ADC) included in the OMP, and a shunt, one output of which is connected to the zero contact of the power supply, and the second with a battery pack and an amplification unit connected to a differential ADC unit that performs the function of inverting the signal, the second input of the differential ADC is connected to the output of the voltage sensor, and the output to the differential of ADC is connected to a corresponding input of the control unit, the signal from which is fed to the PWM unit, an output connected to the input of the amplifier block connected to the block formation of the charge-discharge current control circuit power part.