HU187062B - Circuit arrangement for automativally controlled supply of d.c. load, preferably accumulator tobe chargel according to power consumption - Google Patents

Abstract

The present invention relates to a switching arrangement for automatically feeding a direct current consumer, in particular a rechargeable battery, in which the DC consumer is connected to an AC network through a first switch, a current sensor, a rectifier and a second switch, respectively. According to the present invention, this switching arrangement has a controlled second switch connected to the first output of the control circuit, the control circuit has an input connected through a circuit comparing to the output of the current sensor, a voltage sensor circuit is connected to the common switch and the current sensor. a voltage sensing circuit has an output connected to a further input of the control circuit through a delay circuit. The solution according to the invention eliminates overcharging or charging at a poor power factor. It always provides automatic start and stop. -1-

Description

BACKGROUND OF THE INVENTION The present invention relates to a circuit arrangement for automatically controlling a DC power supply, in particular a rechargeable battery, according to power demand. Various switching arrangements are known for supplying DC power supplies, particularly rechargeable batteries, in which the DC power supply is connected to an AC mains through a switch, current sensor, and rectifier. In these known solutions, the battery is connected directly to the charger directly by plugging in the charging cables without any precautions. On the one hand, this is dangerous because it can cause severe sparking and, on the other hand, does not preclude uncharged and harmful overcharging of fully charged batteries, as an uncontrolled, uncharged battery that is left unchecked can it has the detrimental effect that the charger transformer runs at low power currents for a long time with a poor power factor.

Although charging current is checked by a current sensor or current meter, the charging staff - usually unqualified - usually do not care about monitoring the charging current, especially if batteries of varying degrees are discharged after 1-2 hours of charging. only the state of charge when the charging current is so small that it has no practical use, and at the same time it means unnecessary energy consumption and waste.

It is an object of the present invention to overcome these drawbacks. It is therefore an object of the present invention to provide a switching arrangement in which the power supply to the consumer (battery) can be automatically controlled depending on the current power requirement (charge state), so that no overcharging occurs or charging does not start when a charged battery is connected.

SUMMARY OF THE INVENTION The present invention provides a switching arrangement for automatically controlling a DC power supply, in particular a rechargeable battery, which is connected to an AC mains through a first switch, a current sensor, a rectifier and a second switch in series and having a second switch according to the invention. having an input connected to a first output of a control circuit, an input of a control circuit connected through a circuit comparing an output of a current sensor, a voltage sensor circuit input connected to a common point of the first switch and a current sensor, and a voltage control circuit delay circuit it has an output connected to its other input.

In a preferred embodiment of the circuit arrangement according to the invention, the current sensor has an additional output connected to an additional input of the control circuit via an amperage measuring unit.

In another preferred embodiment, the ammeter unit has an output connected to an input of a resting circuit.

In a further preferred embodiment, the voltage sensing circuit has an output connected to a third input of a controlled switch and a power supply is connected to the mains via the third controlled switch. Advantageously, the control circuit has an additional output connected to a further input of the resting circuit via a fourth switch.

Finally, it is advantageous that the amperage measuring unit is provided with a display unit.

The invention will now be described with reference to an exemplary embodiment, which is illustrated in the accompanying drawings. The figure is a block diagram of an exemplary circuit arrangement.

The switching arrangement shown is intended to supply the DC consumer 1 with automatic control depending on the power demand. The consumer 1 is a partially or fully discharged battery, which must be charged.

The consumer 1 is connected to an AC mains via a first switch 2, a current sensor 12, a rectifier 11 and a second controlled switch 10. The first switch 2 is a manually operated plug or clip connector for connecting the battery to be charged to the system and the second controlled switch 10 is an electronic or electromechanical relay. The rectifier 11, preferably a three-phase unit (optionally equipped with a transformer), and the current sensor 12, for example, are simple shunts, the output of which is connected to the input of a first amperage meter unit 61 and a comparator circuit 7.

At one point of the wire connecting the first switch 2 and the current sensor 12, an input of a voltage sensor circuit 4 is connected. One output of the voltage sensor circuit 4 is connected to the control input of a third controlled switch 3 and the other output is connected to the input of a delay circuit 8. *

The third, controlled switch 3 is inserted in the wiring connecting the power supply 5 to the network. The power supply 5 supplies power to the first amperage meter unit 61 and its associated display unit 62, the comparator circuit 7, and the delay circuit 8.

The first output of the first ampere meter unit 61 is connected to the first input 9 of a control circuit. The second input of the control circuit 9 is connected to the output of the comparator circuit 7, the third input to the output of the delay circuit 8 and the fourth input to the output of the cooling circuit 14. The supply voltage of the relaxing circuit 14 is also provided by the power supply 5. One output of the control circuit 9 is connected to the control input of the second controlled switch 10, the other output is connected via the fourth switch 13 to the first input of the relaxing circuit 14. The second input of the relaxing circuit 14 is coupled to the second output of the first ampere meter unit 61.

The system also includes a second amperage meter unit 63 (shown separately) that is associated with the respective rechargeable battery and an-21

187,062 indicates the current charge or discharge status (as Ah is missing from the second ampero meter 63 units, the amount of Ah to be measured on the first ampero meter 61 after charging is complete).

The circuit layout shown here works as follows:

The second controlled switch 10 receives no control in the normal state, so no voltage is applied to the rectifier 11. The switching of the second controlled switch 10 is triggered by the manual switching of the first switch 2, such that the voltage sensor circuit 4 senses the voltage of the battery (consumer 1) after the switch 2 is closed (the charging cable is connected to the battery corners). a third controlled switch 3 (through which the power supply 5 is supplied and thus supplied directly to the units 61, 62 and the circuits 7, 8, 14), on the other hand, activates the delay circuit 8.

After the set delay, the delay circuit 8 provides a start signal to the control circuit 9, which activates the second controlled switch 10. Thus, the rectifier 11 is supplied with mains voltage, and the current sensor 12 and the already closed first switch 2 begin to supply (charge) the consumer (battery).

The current sensor 12 provides a signal proportional to the charge current, which is supplied to the first amperage meter unit 61 and to the comparator circuit 7, respectively. The first ampere meter unit 61 measures the amount of Ah loaded, which can be read on the display unit 62. The comparator circuit 7 has an adjustable reference value. If the signal provided by the current sensor 12 is greater than this reference value, the comparator circuit 7 also provides a control command to the control circuit 9, confirming that the switch 10 has already been turned on. The charging current is maintained as long as the signal from the current sensor 12 is greater than the reference value.

As the charge current decreases as the battery charges, at some point in the charging process (preferably at 95% charge), the signal provided by the current sensor 12 is reduced to a reference value set accordingly in the comparator circuit when circuit 7 is off! gives command to the control circuit 9 and thus switch 10 is switched off (charging is interrupted). Since the current sensor 12 then supplies a signal 0, which is clearly less than the reference value of the circuit 7, the resulting shutdown confirms itself.

If, after closing the first switch 2, the signal of the current sensor 12 does not reach the reference value set by the comparator circuit 7 even after the set delay of the delay circuit 8 (for example, due to negligence or lack of measurement data, a fully charged battery or ), the comparator circuit 7 commands the control circuit 9 to turn off the switch 10. This saves a fully charged battery from overcharging (which also saves power), and the contacts of the faulty switch and the connecting leads from sunburn.

Otherwise, in the event of a contact failure of the first switch 2, the voltage sensor circuit 4 also provides protection because, in the absence of a proper voltage level, it switches off the third controlled switch 3 and thereby switches the? The power supply 5, that is, the units 61, 62 and the circuits 7, 8, 14 are not supplied with power, so that the control circuit 9 cannot activate the second controlled switch 10. Of course, the same applies if the mains voltage is left out.

If sustained charging occurs, after reaching the set 95% charge, the missing 5% is charged such that the control circuit 9 initiates the sleeper circuit 14 through the fourth switch 13, which after a set 1-2 hour rest period It commands the control circuit 9 to re-enable switch 10. The charging current starts as described above and persists until switch 2 is turned off or the first amperage meter unit 61 (which measures the total charge charged) stops the charging process permanently. The Ah value required for power supply is given by the Ah capacity of the battery when fully discharged, and by the second amperage meter of the battery in the case of a partially discharged battery! measured value (amount of charge taken during use to fill the charge).

The following circuitry has the following advantages: Charging starts automatically when the battery is connected. The set delay protects the connectors and wires from sunburn in case of contact failure (fire protection).

The charging current is switched off automatically when the desired (set) charge state is reached.

During the message, it is also possible to switch off the battery manually by disconnecting the battery, since the current sensor 12 and voltage sensor 4 automatically stop charging in a few ms and prevent electrical sparking (fire protection). This also applies if the circuit is interrupted by an error.

Poor performance of rectifier transformer 11 (with low charge current) is eliminated by switching off the comparator circuit 7 at low charge current and then restarting the charging circuit 14 after a set 1-2 hours of rest.

Measuring the amount of charge removed from the battery ensures that the required amount of charge can be accurately set.

In the event of a power failure or a transformer short-circuit, the system will also turn off automatically.

Claims (6)

Patent claims 1. A circuit arrangement for automatically controlling a DC power supply, in particular a rechargeable battery, according to the power demand, wherein the DC power supply is directly connected in series with a first switch, a current sensor3. -3 ' 187,062 connected via a controller and a second switch to an AC network, characterized in that it has a controlled second switch (10) whose input is connected to a first output of a control circuit (9), a price meter (12) of the control circuit (9). ) has an input connected to an output via a comparator circuit (7), a voltage sensor circuit (4) input is connected to a common point of the first switch (2) and a current sensor (12), and a voltage detector circuit (4) via 10 delay circuits (8) an output connected to an additional input of the control circuit (9). An embodiment of a circuit arrangement according to claim 1, characterized in that the current sensor (12) has an additional output connected to an additional input of the control circuit (9) via an amperage measuring unit (61). An embodiment of the circuit arrangement according to claim 2, characterized in that the amperage measuring unit (61) has an output connected to an input of a resting circuit (14). Embodiment of the circuit arrangement according to claim 1, characterized in that the voltage detection circuit (4) has an output connected to a control input of a third controlled switch (3) and a power supply (5) via the third controlled switch (3). connected to the network. An embodiment of a circuit arrangement according to any one of claims 1 to 3, characterized in that the control circuit (9) has an additional output connected to a further input of the relaxing circuit (14) via a fourth switch (13). An embodiment of a circuit arrangement according to claim 2 or 3, characterized in that the amperage measuring unit (61) is provided with a display unit (62).