RU2219639C2 - Device for high-speed charging of storage battery with asymmetric current - Google Patents

Abstract

FIELD: electrical engineering; battery charging using rectifier-inverter units. SUBSTANCE: device some of whose components perform more than one function has control circuit that functions according to given algorithm and power section control circuit characterized in reduced number of components. Control unit in the form of singlechip microprocessor generates signals in compliance with algorithm for charging and synchronizing from supply-mains to control bidirectional rectifier and bilateral switch. Storage battery connected to rectifier functions as its load. One plate of each of current-limiting capacitors is connected to supply mains. Other plate of charging capacitor is connected to bidirectional controllable rectifier and other plate of discharge capacitor is connected to bilateral switch whose other end is connected to other plate of charging capacitor and to bidirectional controllable rectifier. Limiting current during charging and discharging periods enables rectifier control dispensing with phase control. EFFECT: reduced mass and size of device due to joint execution of some functions by circuit components; simplified circuit arrangement due to reduced number of components. 1 cl, 1 dwg

Description

 The invention relates to electrical engineering, in particular to devices for accelerated charging of batteries based on charge-discharge rectifier-inverter converters.

 A known device made on the counter-parallel connected controlled thyristor bridges [1].

 A disadvantage of the known device is the fixed range of setting the asymmetric current modes at a given input voltage and the complexity of implementing changes in the range of the mode setting. When charging batteries, the task of charging batteries with a different number of cells arises. In this case, to set the charge mode, it is necessary to adjust the parameters of the charger, namely the magnitude of the input voltage and charge-discharge currents. The value of the input voltage of the charger is selected as the sum of the maximum EMF of the battery and the maximum overvoltage under current at the end of the charge, and the charge-discharge currents are regulated by phase control within a given range of the supply voltage. With a decrease in the number of batteries in the battery by more than 10 pcs. the device does not allow maintaining the battery charge in a predetermined asymmetric current mode with a fixed input voltage. To maintain the specified mode, it is necessary to create a certain ratio of the average values of the charging and discharge currents, therefore, the adjustment of the controlled bridges must be carried out at small opening angles of the thyristors with large pulse amplitudes of the charging and discharge currents. This leads to the heating of the batteries and does not make it possible to implement a charge algorithm. With an increase in the number of accumulators in the battery at a fixed input voltage, the average value of the charging current sharply decreases, because the value of the fixed input voltage is optimal when providing the specified value of the asymmetric current mode at the maximum possible opening phase of the controlled thyristor bridge, and with an increase in the voltage on the battery, the angle of adjustment decreases , and consequently, the average values of the charging current. Switching the output voltage of the device to charge batteries with a different number of cells will complicate the entire device.

 Closest to the proposed technical solution is [2] a device for accelerated battery charging with an asymmetric current, comprising a control circuit according to a predetermined algorithm, including: a control unit, which is a single-chip microprocessor, an indication unit, a charge algorithm task unit, a charge mode task unit, a unit voltage sensor, the output of which is connected to the input of the control unit, a synchronization unit consisting of working and initial synchronization blocks, the inputs of which are combined, and the outputs connected to the control unit, a power supply connected to the output with the input of the synchronization unit, and an input to the output of the charge mode setting unit, a voltage sensor unit connected to the terminals for connecting the battery, and a power section control circuit including a filter unit, charging and discharge units capacitors, two counter-parallel connected blocks of controlled rectifiers, amplifier blocks, the outputs of which are connected to the corresponding inputs of the blocks of controlled rectifiers, and the inputs to the corresponding outputs Lok management. The control unit generates signals in accordance with the charge algorithm and synchronization from the network to control counter-parallel connected controlled rectifiers. As a load, a battery is connected to the rectifiers. Some plates of current-limiting capacitors are connected to the mains, while other plates are connected to controlled rectifiers. The current limitation in the charging and discharge periods of operation allows you to control the rectifiers without phase control. The presence of separate blocks of charging and discharge capacitors and a large number of power controlled elements on radiators mainly determines the mass and dimensions of the device.

 The objective of the invention is to simplify the power part, reducing the mass and dimensions of the device by combining the functions performed by individual elements.

 The problem is achieved in that in a device for accelerated charging of batteries with an asymmetric current, comprising a power unit control circuit including a filter unit, a charging capacitor unit, a discharge capacitor unit and an amplifier unit, and a control circuit according to a predetermined algorithm including a control unit, an indication unit , a charge algorithm setting unit, a charge mode setting unit, a synchronization unit, a power supply connected to the input of the synchronization unit by an output, and a voltage sensor unit whose inputs connected to the terminals for connecting the batteries, and the output is connected to the control unit, the outputs of the control unit are connected to the corresponding inputs of the amplifier unit of the power unit control circuit, an amplifier unit is introduced, the input of which is connected to the output of the control unit, a symmetric key whose input is connected to the output of the unit amplifiers, one end of the symmetric key is connected to the block of discharge capacitors, and the other to the block of charging capacitors and a symmetrical controlled rectifier, the inputs of which are connected to corresponding outputs of the amplifier block. The introduction of a symmetric key made it possible to use a controlled rectifier on symmetric elements - triacs to create an asymmetric current.

 The use of triacs as a symmetric key and elements of a controlled rectifier can simplify the power part of the device, and therefore, reduce the weight and dimensions of the installation. This is especially important when creating installations for high charge currents.

 The drawing shows a block diagram of a device.

 The device includes a control system according to a predetermined algorithm (CPS) 1 and a power control system (CMS) 2. The control unit 3, which is a single-chip microprocessor, is connected to the synchronization unit 4, which consists of the initial synchronization unit 5 and the working synchronization unit 6, an indication unit 7, a charge mode setting unit 8, a charge algorithm setting unit 9, which physically can be made integrally with a control unit 3, a voltage sensor unit 10, amplifier units 11 and 12. The power supply unit 13 is connected to the mains voltage terminals, the input is connected to the output of the charge mode setting unit 8, and the output to the synchronization unit 4. The outputs of the blocks 11 and 12 of the amplifiers are connected to a block 14 of a symmetrical controlled rectifier and a block 15 of a symmetric key, respectively, made on triacs. The positive terminal of the symmetrical controlled rectifier unit 14 has a terminal for connecting the positive terminal of the battery 16. The negative terminal of the symmetrical controlled rectifier unit 14 has a terminal for connecting the negative terminal of battery 16. The terminals for connecting battery 16 are connected to voltage sensor block 10. One terminal for connecting the alternating voltage of the symmetrical controlled rectifier unit 14 is connected to the charging capacitor unit 17 and the symmetric key unit 15, the other end of which is connected to the discharge capacitor unit 18. The second output is connected to the output of the filter unit 19. The inputs of the blocks 17 and 18 of the charging and discharge capacitors, respectively, are combined and connected to another output of the filter block 19, the inputs of which have conclusions for connecting to the mains.

 The device operates as follows. The power-on signal of the power supply unit 13 comes from the charge mode setting unit 8. The power supply unit 13 generates a stabilized voltage for supplying the control unit 3, the indication unit 7, the charge algorithm setting unit 9, the voltage sensor unit 10, the initial synchronization unit 5 and the operational synchronization unit 6. The rectified and smoothed voltage is supplied to the amplifier blocks 11 and 12 with a delay for the duration of transients in the control unit 3 to prevent accidental opening of the power elements in the blocks 14 and 15 of the symmetrical controlled rectifiers and the symmetric key, respectively. Alternating voltage from the secondary winding of the transformer of the power supply unit 14 is supplied to the initial synchronization unit 5 and the working synchronization unit 6. The output of block 5 of the initial synchronization is a rectangular signal with a duration of 10 ms and a frequency of 50 Hz. The leading edge of the pulse corresponds to the transition of the sinusoid of the supply voltage from minus to plus. The synchronization signal enters the control unit 3 for matching the control pulses with the frequency and polarity of the supply network and serves for the initial charge of the capacitors in blocks 17 and 18 of the charging and discharge capacitors, respectively. The output of the working synchronization block 6 is a rectangular signal with a duration of 10 ms and a frequency of 50 Hz. The leading edge of the pulse corresponds to the transition of the sinusoid of the supply voltage through the maximum value. The working synchronization signal is supplied to the control unit 3 for matching the control pulses of the symmetrical controlled rectifiers unit 14 and the symmetric key unit 15 with the frequency and polarity of the supply network during the execution of the charge algorithm. The control unit 3 is started by a signal from the charge mode setting unit 8 and executes the charge algorithm recorded in the charge algorithm setting unit 9. On the block 7 of the indication receives signals about the operation of the charger from the control unit 3. The signal from the voltage sensor unit 10 is supplied to the control unit 3 and is processed in accordance with the charge algorithm. The signals to the block 14 of the charge-discharge symmetric controlled rectifier and the block 15 of the symmetric key come from the control unit 3 to the inputs of the amplifier blocks 11 and 12, respectively, which amplify the control signals and perform galvanic isolation of the control circuits from the power circuits. Block 19 of the filters serves to suppress high-frequency interference of the network and is an inductive capacitive T-shaped filter. The charging capacitor unit 17 limits the charge current of the battery 16, and in the discharge periods, the symmetric key of the block 15 is turned on, and the current is limited by the total capacity of the discharge capacitors of the block 18 and the charging capacitors of the block 17. To the symmetrical controlled rectifiers of the block 14, the battery 16 is included as a load. The polarity of the output voltage of the symmetric controlled rectifier is determined by the sequence of control pulses from the control unit 3. The ratio of the amplitudes of the charging and discharge pulses is provided by the value of the capacitance of the block 17 of the charging capacitors and the value of the total capacity of the block 18 of the discharge capacitors and the block 17 of the charging capacitors. The number of charge and discharge pulses is determined in accordance with the charge algorithm.

 The introduction of the symmetric key block 15 to combine the capacities of the charging and discharge capacitors blocks 17 and 18 to create the amplitude of the discharge current determined by the charge mode makes it possible to simplify the power part of the circuit using symmetric power elements - triacs - in the symmetric key block 15 and the symmetrical controlled rectifiers block 14. Reducing the number of power elements can reduce the weight and dimensions of the device.

Sources of information:
1. USSR author's certificate 1056360, N 02 J 7/10, 1983.

 2. Patent of the Russian Federation 2134476, H 02 J 7/10, 1999.1

Claims (1)

A device for accelerated charging of a battery with an asymmetric current, comprising a control circuit according to a predetermined algorithm, including a control unit connected to a synchronization unit, an indication unit, a charge algorithm setting unit, a charge mode setting unit, a voltage sensor unit, while the charge mode setting unit is connected to a power supply unit, which is connected to a synchronization unit, consisting of operating and initial synchronization units, a voltage sensor unit is connected to a battery, and a control circuit the power part, including a filter unit connected to the blocks of charging and discharge capacitors, an amplifier block, the input of which is connected to the output of the control unit, characterized in that a symmetric key unit is connected to the control circuit of the power part, connected by one output to the block of discharge capacitors, the second one with a block of charging capacitors, a block of symmetrical controlled rectifiers connected to a common point of the block of a charging capacitor and a block of a symmetric key, with the output of a filter block, with a battery and with the output of the amplifier block, the amplifier block, the output of which is connected to the input of the symmetric key block, and the input to the control unit.