CS250340B1 - Static source connection for accumulators' charging and discharging - Google Patents

Abstract

The purpose of engagement is to eliminate shortcomings existing battery chargers, an option controlled charging and discharging of batteries, its disconnection by the final assessment Charging or Discharging Characters; charging characteristics by manual intervention a contactless blocking of the source function at incorrect connection to the mains or battery. This purpose is achieved by engagement a static source that contains circuits protection, synchronization and interference suppression, galvanic Separation and transfer of voltage, rectifiers, filtration, 'contact reversing, sensors current and controller circuit. The controller circuit is composed of circuits reference voltage, outage and sequence sources phase, ignition pulse generator, timing, battery polarity check, amplifiers and output polarity switches voltage, amplifier and current comparator current regulator, level and polarity switches output voltage, voltage regulator, voltage level comparator, mode selection, reversing logic, logic evaluation load condition, signaling, and measurement circuit derivative of output current.

Description

The invention relates to a static source for charging and discharging accumulators.

The currently used charging sources serve as a charger of one or more types of accumulators with the possibility of selecting several charging characteristics, where the charge is determined mainly by the time interval of some of the characteristics. These sources do not allow discharge control, for example for battery formation, and charge size is not judged by the final charge, but only by the charging time. The discharge function for capacitance and life tests is provided by separate discharge devices that only allow discharges by obstructing energy in passive resistances.

These disadvantages are overcome by the connection of a static source for charging and discharging the accumulators according to the invention, consisting of:

protection, synchronization and interference suppression circuit, galvanic isolation and voltage transfer circuit, rectifier circuit, filter circuit, contact reversal circuit, current sensor circuit, current regulator circuit, reference voltage source circuit, power failure and phase sequence circuit, ignition pulse generator circuit, timing circuit , battery polarity control circuit, amplifier and output voltage polarity switch circuit, amplifier and current comparator circuit, current regulator circuit, output voltage level and polarity switch circuit, voltage regulator circuit, voltage level comparator circuit, mode selection circuit, reverse logic circuit, circuit load logic, signaling circuit, and output current derivative measurement circuit.

The input terminal is connected to the fuse, synchronization and interference suppression input, whose first output is connected to the input of the galvanic isolation circuit and the voltage transformation. Its output is connected to the first input of the rectifier circuit, the second output of which is connected to the second input of the reversing circuit.

(The first rectifier circuit output is coupled to the filter circuit input, whose output is coupled to the first reverse circuit input.

The second output of the reversing circuit is connected to the input of the current sensor circuit, the first output of which is connected to the output terminal. The second output of the fuse, synchronization and interference suppression circuit is coupled to the input of the reference voltage source circuit and at the same time to the input of the outage and phase sequence circuit, the first input of the ignition pulse generator circuit and the first input of the timing circuit.

The output terminal is connected to the battery polarity check circuit input and the amplifier and output voltage polarity switch input. The second output of the current sensor circuit is connected to the input of the amplifier and current comparator circuits. The first output of the ignition pulse generator circuit is coupled to the second rectifier circuit input.

The first reverse logic circuit output is coupled to the third reverse circuit input. The first output of the reference voltage source circuit is coupled to the first input of the current regulator circuit and the second output is coupled to the first input of the level switch and output voltage polarity. Its output is connected to the first input of the voltage regulator circuit.

The first output of the amplifier and voltage level comparator circuit is coupled to the second input of the current regulator circuit and simultaneously to the first input of the output current derivative measurement circuit. The output of the amplifier circuit and the output voltage polarity switch is connected to the second input of the voltage regulator circuit. The output of the voltage regulator circuit is connected to the first input of the voltage level comparator circuit and simultaneously to the third input of the ignition pulse generator circuit.

The second input of the ignition pulse generator is coupled to the output of the current regulator circuit and simultaneously to the second input of the voltage level comparator circuit. The mode selection circuit output is coupled to a second output of the amplifier and output voltage polarity switch circuit, along with a second input of the level and output voltage polarity switch circuit, a first reverse logic circuit input, a third timing circuit input, a first load state evaluation logic circuit input the first input of the signaling circuit.

The second output of the amplifier and current comparator circuits is connected to the second input of the reverse logic circuit, the third input of which is connected to the second output of the ignition pulse generator circuit. The second reverse logic circuit output is coupled to the fourth ignition pulse generator circuit input, the first voltage level comparator circuit output, the first outage and phase sequence output, and the first battery polarity check circuit output.

The second load state logic circuit output, the second voltage level comparator circuit output, the second outage and phase sequence output, and the second battery polarity control circuit output are coupled to the second signaling circuit input. The second input of the output current derivative measurement circuit is coupled to the second output of the timing circuit. Circuit output

The output current derivative measurement 230340 is coupled to the second input of the load condition evaluation logic circuit, the third input of which is coupled to the first output of the timing circuit.

The third output of the timing circuit is coupled to the third input of the output voltage level and polarity switch circuit. The second timing circuit input is coupled to the third load state evaluation logic output, the first output of which is coupled to the fourth ignition pulse generator circuit input.

The reversing block can be replaced by two controlled rectifiers in a reverse circuit in the rectifier circuit.

The static source according to the invention enables controlled charging of the accumulator or its discharging by energy recuperation into the mains, contactless or contact disconnection of the accumulator by assessing the final signs of charging or discharging the accumulator and mixing its electrolyte by timed increase of the charging voltage.

Furthermore, it enables the charging characteristics to be influenced by manual intervention, which allows full charging of older accumulators with a safety time limitation when charging at a higher voltage level than the gassing voltage of the accumulator. In addition, it enables contactless blocking of the power supply function when incorrectly connected to the battery or the mains and desulphating sulphate damaged batteries.

The figure shows the connection of the static source according to the invention in a block diagram.

Specific embodiments

The input terminal 1 is connected to the input 21 of the protection, synchronization and interference suppression circuit 2. Its first output 22 is coupled to the input 31 of the galvanic isolation and voltage transformer circuit 3, whose output 32 is coupled to the first input 41 of the rectifier circuit 4. Its second output 43 is connected to the second input 63 of the reversing circuit 6.

The first output 42 of the rectifier circuit 4 is connected to the input 51 of the filter circuit 5, the output 52 of which is connected to the first input 61 of the reversing circuit 6. Its second output 62 is connected to the input 71 of the current sensor circuit 7, the first output 72 of which is connected to the output terminal 8.

The second output 23 of the protection, synchronization and interference suppression circuit 2 is connected to the input 141 of the reference voltage source circuit 14 and at the same time to the input 211 of the failure and phase sequence circuit 21, the first input 151 of the ignition pulse generator circuit 15 and the first input 191 of the timing circuit 19. The output terminal 8 is connected to the input 221 of the battery polarity control circuit 22 and the input 101 of the amplifier circuit 10 and the output voltage polarity switch.

The second output 73 of the current sensor circuit 7

S is connected to the input 91 of the amplifier and current comparator circuit 9. The first output 152 of the ignition pulse generator circuit 15 is coupled to the second input 44 of the rectifier circuit 4. The first output 171 of the reversing logic circuit 17 is coupled to the third input 64 of the reversing circuit 6.

The first output 142 of the reference voltage source circuit 14 is coupled to the first input

111 Current regulator circuit 11. The second output 143 of the reference voltage source circuit 14 is coupled to the first input 131 of the output voltage level and polarity circuit 13, whose output 132 is coupled to the first input 121 of the voltage regulator circuit 12. The primary output 92 of the amplifier and comparator circuit 9 is coupled to the second input

112 of the current regulator circuit 11 and simultaneously with the first input 201 of the output current derivative circuit 20.

The output 102 of the amplifier circuit and output voltage polarity switch is coupled to the second input 122 of the voltage regulator circuit 12, the output 123 of which is coupled to the first input 161 of the voltage level comparator circuit 16 and simultaneously to the third input 154 of the ignition pulse generator circuit. The second input 153 of the ignition pulse generator circuit 15 is coupled to the output 113 of the current regulator circuit 11 and simultaneously to the second input 164 of the voltage level comparator circuit 16.

The output 231 of the mode selection circuit 23 is coupled to the second input 103 of the amplifier and output voltage polarity switch 10, at the same time as the second input 133 of the output voltage and polarity switch circuit 13, to the first input 172 of the reverse logic circuit 17. timing, by the first input 181 of the load condition evaluation logic 18 and with the first input 241 of the signaling circuit 24.

The second output 93 of the amplifier and current comparator circuit 9 is connected to the second input 173 of the reverse logic circuit 17, the third input 174 of which is connected to the second output 155 of the ignition pulse generator circuit 15. The second output 175 of the reverse logic circuit 17 is coupled simultaneously to the fourth input 156 of the ignition pulse generator circuit 15, the first output 162 of the voltage level comparator circuit 16, the first output 212 of the phase and phase sequence circuit 21, and the first output 222 of the battery polarity control circuit 22.

The second output 183 of the load condition evaluation logic 18, the second output 163 of the voltage comparator circuit 16, the second output 213 of the phase and phase sequence circuit 21, and the second output 223 of the battery polarity control circuit 22 are connected to the second input 243 of the signaling circuit 24. The second input 202 of the output current derivative measurement circuit 20 is coupled to the second output 194 of the timing circuit 19.

The output 203 of the output current derivative measurement circuit 20 is connected to a second input 184 of the load state evaluation logic 18, the third input 185 of which is connected to the first output 192 of the timing circuit 19. The third output 196 of the timing circuit 19 is coupled to the third input 134 of the output voltage level and polarity switch circuit 13. The second input 193 of the timing circuit 19 is coupled to the third output 186 of the load state evaluation logic 18, the first output 182 of which is coupled to the fourth input 156 of the ignition pulse generator circuit 15.

The supply voltage 3 380 380 V from input terminal 1 is fed through circuit 2 of protection, synchronization and interference suppression and circuit 3 of galvanic isolation and transformation of voltage to circuit 4 of the rectifier. Its output 43 is applied via the reversing circuit 6 and the current sensor circuit 7 to the output terminal 8, to which the battery load is connected. The rectifier circuit 4 includes a controlled rectifier and an uncontrolled DC auxiliary power supply to power the auxiliary circuits.

By means of ignition pulses from the pulse generator circuit 15, a controller composed of circuits 9 to 24 controls the output volt-ampere characteristics over time. The correct connection of the static source to the network is ensured by the phase and phase sequence circuit 21, which in case of incorrect phase sequence or absence of any of the phases disconnects it contactlessly from the load. Similarly, the battery polarity control circuit 22 operates to block the static source function in the event of incorrect battery connection or disconnection of the measurement feedback line.

The mode selection circuit 23 allows the choice of automatic charging or discharging, possibly manual control of the output current, with the possibility of introducing a voltage jump at any time to mix the electrolyte. The output voltage characteristics are provided by the current regulator circuit 11 and the voltage regulator circuit 12. Desired voltage levels or load current levels are controlled by the reference voltage source circuit 14 and the output voltage level and polarity switch circuit 13.

The actual value of the output voltage is processed by the amplifier circuit 10 and the output voltage polarity switch. The actual value of the output current from the current sensor circuit 7 is amplified in the amplifier and current comparator circuit 9. The information about reaching the desired output voltage levels is processed by the voltage level comparator circuit 16 in the load state evaluation logic 18. The reverse logic circuit 17 provides a trouble-free transition from charge to discharge mode and vice versa.

If manual operation is not selected, the charging cycle is fully automatic. When the gassing voltage is reached when charging with a constant current, the static source automatically enters the constant output voltage mode. The automatic termination of the charging and the contactless disconnection of the battery is performed after reaching the final charge characteristics by the load evaluation circuit 18. The charge state of the load is periodically determined by measuring the charge current increment by the output current derivative measurement circuit 20.

The achievement of the desired value of this derivative is evaluated by the load condition evaluation logic circuit 18. The timing circuit 19, which operates at multiples of the line frequency, determines the measurement intervals of the output current derivative measurement circuit 20. At the same time, in the manual control mode and reaching the battery voltage limit, the contactless disconnection after a fixed protection time has elapsed via the circuit 18 of the load logic logic.

Furthermore, it ensures a safe mixing cycle time through the output voltage level and polarity switch circuit 13. The discharge cycle is terminated automatically upon reaching one of the two fixed voltage levels corresponding to the rated discharge mode and / or rapid discharge by contactless shutdown via the load condition logic circuit 18 and signaled as well as the completion of the charging cycle in the signaling circuit 24.

Requirements for blocking the operation of a static source in a fault condition, or for contactless disconnection when the desired condition is achieved from the power failure and phase sequence circuits, 18 load condition evaluation logic, 16 voltage level comparator, 17 reversing logic and battery polarity check 22, Ignition pulses, The 'Signal Circuit' 24 signals operating and fault conditions.

Claims (2)

SUBJECT Static power supply circuit for charging and discharging accumulators, consisting of a protection, synchronization and suppression circuit, a galvanic isolation and voltage transfer circuit, a rectifier circuit, a filtration circuit, a contact reversal circuit, a current sensor circuit, a current regulator circuit, a reference voltage source circuit, power failure circuit and phase sequence, ignition pulse generator circuit, timing circuit, battery polarity control circuit, amplifier and output voltage polarity switch circuit, amplifier and current comparator circuit, current regulator circuit, output voltage level and polarity switch circuit, voltage regulator circuit, circuit voltage level comparator, mode selection circuit, reverse logic circuit, load state evaluation logic circuit, signaling circuit, and output current derivative measurement circuit, characterized in that the input terminal (1) is connected to the input (21) of the circuit (2) The first output (22) is connected to the input (31) of the galvanic isolation circuit (3) and the voltage transformer, whose output (32) is connected to the first input (41) of the rectifier circuit (4), the second the output (43) is connected to the second input (63) of the reversing circuit (6) and the first output (4,2) of the rectifier circuit (4) is connected to the input (51) of the filtering circuit (5) whose output (52) is coupled a first input (61j) of the reversing circuit (6), the second output (62) of which is coupled to the input (71) of the current sensor circuit (7), the first output (72) of which is coupled to the output terminal (8); (23) the protection, synchronization and interference suppression circuit (2) is coupled to the input (141) of the reference voltage source circuit (14) and at the same time to the input (211) of the failure and phase sequence circuit (21); 15) an ignition pulse generator and a first input (191) of the timing circuit (19), wherein the output terminal (8) is sp the input (221) of the battery polarity control circuit (22) and the input (101) of the amplifier circuit and output voltage polarity switch (101), the second output (73) of the current sensor circuit (7) being coupled to the circuit input (91). 9) an amplifier and a current comparator, the first output (152) of the ignition pulse generator circuit (15) is coupled to the second input (44) of the rectifier circuit (4), and the first output (171) of the reverse logic circuit (17) is coupled to the third input ( 64) a reversing circuit (6) wherein the first output (142) of the reference voltage source circuit (14) is coupled to the first input (111) of the current regulator circuit (11) and the second output (143) of the reference voltage source circuit (14) is coupled with a first input (131) of an output voltage level and polarity switch circuit (13) of which OF THE INVENTION the output (132) is coupled to the first input (121) of the voltage regulator circuit (12), the first output (92) of the amplifier and current comparator circuits (9) being coupled to the second input (112) of the current regulator circuit (11) with the first input (201) of the output current derivative circuit (20), the output (102) of the amplifier circuit (10) and the output voltage polarity switch is coupled to the second input (122) of the voltage regulator circuit (12) coupled to a first input (161) of the voltage level comparator circuit (16) and simultaneously to a third input (154) of the ignition pulse generator circuit (15), the second input (153) of which is connected to the output (113) of the current regulator circuit (11); at the same time as the second input (164) of the voltage level comparator circuit (16), wherein the output (231) of the mode selection circuit (23) is coupled to the second input (103) of the amplifier circuit and output voltage polarity switch a power input (133) of the output voltage level and polarity switch circuit (133), with a first input (172) of the reverse logic circuit (17), a third input (195) of the timing circuit (19), a first input (181) of the circuit (18) the load state evaluation logic and the first input (241) of the signaling circuit (24), the second output (93) of the amplifier and current comparator circuit (9) being coupled to the second input (173) of the reversing logic circuit (17); is connected to the second output (155) of the ignition pulse generator circuit (15) and the second output (175) of the reverse logic circuit (17) is coupled simultaneously to the fourth input (156) of the ignition pulse generator circuit (15), the first output (162) the voltage level comparator circuit (16), the first outage (212) of the power failure circuit (21) and the phase sequence, and the first output (222) of the battery polarity control circuit (22), the second output (183) of the load condition evaluation logic (18) e, the second output (163) of the voltage level comparator circuit (16), the second output (213) of the power failure and phase sequence circuit (21) and the second output (223) of the battery polarity control circuit (22) are coupled to the second circuit input (243) (24) signaling, the second input (202) of the output current derivative measuring circuit (20) is coupled to the second output (194) of the timing circuit (19), and the output (203) of the output current derivative measuring circuit (20) is coupled to the second input ( 184) a load condition evaluation logic circuit (18) whose third input (185) is coupled to a first output (192) of the timing circuit (19) whose third output (196) is coupled to a third input (134) of the switch circuit (13) level and polarity of the output voltage, the second input (193) of the timing circuit (19) being coupled to the third output (186) of the load state evaluation logic (18), the first output (182) of which is connected to the fourth input (156) 15) ignition generator impulses. Static source connection according to claim 1, characterized in that the reversing block (6) is replaced by two controlled rectifiers in a reversing circuit in the rectifier circuit (4).