HU207618B - Battery charger with current control - Google Patents

Abstract

FIELD OF THE INVENTION The present invention relates to a current controlled battery charger in which a direct control unit (1) connected to an AC mains terminal (11), preferably via one or more circuit switches (K), is operable to connect a coupled passage unit (2) and a battery. a clamp (12), optionally a control unit (4) and / or a voltage monitoring unit (5) connected to this terminal (12), a current sensor (3) inserted between the rectifier unit (1) and the terminal for connecting the battery (12) - preferably measuring resistor - and a current monitor (6) connected to it, the output of the current monitor (6) is connected to the input of the amplifier (7), the output of this amplifier (7) is connected to the control input (13) of the passage unit (2), the voltage monitoring unit (5) The rule of permeability (2) is also connected directly or via the amplifier (7) (13), and the control unit (4) is connected to the switch (K) by means of a relay closing contact (s) (JE) parallel to the switch (K). The essence of the invention is that the current monitor (6) is a peak rectifier whose output has a variable resistance, the peak rectifier input is the input of the current monitor (6) and the output of the peak rectifier is the output of the current monitor (6). Figure 20 EN 207 618 B Scope of the description: 6 pages (including 2 sheets)

Description

BACKGROUND OF THE INVENTION The present invention relates to a current-controlled battery charger comprising a rectifier connected to an AC mains terminal, preferably a single or multi-circuit switch, a terminal connected thereto and a battery, optionally a control unit and / or a voltage monitoring unit. a current sensor - preferably a measuring resistor - and a current monitor connected thereto are connected between the rectifier unit and the terminal for connecting the battery, connected to the amplifier input of the current monitor output connected to the regulator input of the bypass unit, the voltage monitoring unit connects to the regulator input of the bypass unit and the control unit connects to the switch parallel to the switch by means of a closing relay contact (s),

The battery charger according to the invention is suitable for charging the battery with current pulses, the so-called regenerative charge, with controlled current, optionally to regulate the charging current at the end of the charging process, depending on the terminal voltage of the battery or to switch the charging device dependent on the terminal voltage. Thus, its main applications include time-saving battery charging, partial restoration of the original amperage capacity of sulphate batteries, and batteries that are permanently out of service, eg. unattended charging and maintenance of batteries for agricultural equipment that has been shut down for winter.

Power regulator battery chargers are widely used. The main reason for their widespread use is that the mean value of the charge current during charging is approximated well, i.e. it does not decrease with the increase of the terminal voltage of the charged battery and thus the charging process is not delayed. In another approach, adjusting a more or less constant charge current does not require intervention from the operator from time to time. Most of them have a smoothing capacitor connected to the output of their rectifier unit. Such a charger is known e.g. radio technology yearbook 1971.96. page 23. Smooth charging current provides high quality electronic charging current control. However, it is known that charging with pulsating DC is advantageous for battery life. In this case, however, one-off! devices make current control difficult. As a result, they are either waived or replaced by a limiting resistor in the charging current path. An example of the latter is the circuit shown in Figure 9 of the Radiocommunication Yearbook 1981, page 53. However, this solution requires an oversized power transformer supplying the rectifier, and the requirement for a preset constant current charge can only be approximated.

Known battery chargers typically include a voltage monitor unit which is designed to automatically ensure that the charging current is strongly controlled at the end of the charging process, thereby preventing overcharging of the battery.

There are examples of battery chargers that can be operated unattended for long periods of time. In a group of solutions, the control unit switches the charger on and off, depending on the battery terminal voltage, to which the battery is permanently connected.

These latter two functions, with many more to accompany, usefully complement the control of the charging current during charging, extending the potential application of battery chargers.

It is therefore an object of the present invention to provide a current-controlled battery charger which is capable of controlling the charging current during charging by simple means by charging the battery with current pulses.

The present invention is based on the recognition that the desired result is achieved if a current monitor connected to the current sensor of the charger of the present invention is a peak rectifier with an output of a variable resistor for adjusting the load current as a load. The output voltage of the loaded peak rectifier can then be used for current control.

Accordingly, the present invention provides a price regulator battery charger comprising a rectifier unit connected to an AC power terminal, preferably one or more circuit switches, a terminal for connecting a serial throughput unit and a battery, optionally a control unit connected to this terminal and / or a current sensor, preferably a measuring resistor, is arranged between the voltage monitoring unit, the rectifier unit and the terminal for connecting the battery, and a current monitor connected thereto is connected to the amplifier input of the current monitor connected to the regulator input of the bypass unit; it is also connected via the amplifier to the regulator input of the bypass unit and the control unit to the grid resides on the switch using relay closing contact (s) that bridges the switch in parallel. According to the invention, the current monitor is a peak-level controller with a variable resistance connected to its output, the peak rectifier input being the current monitor input and the peak rectifier output the current monitor output.

It is advantageous to connect a diode anode of one of the two terminals of the current sensor with a more positive potential during operation, one terminal of a capacitor and a potentiometer, a cathode of the diode and another terminal of a capacitor and a potentiometer. its slider is connected and connects to the amplifier input.

The solution will be described in more detail by way of an exemplary embodiment, by means of drawings. The

Fig. 1 is a block diagram of a power control battery charger according to the invention, a

Fig. 2 shows an exemplary circuit diagram of a battery charger.

HU 207 618 Β

Fig. 1 shows that a rectifier unit (1) connected to an AC mains terminal (11) in an exemplary power regulator battery charger according to the invention can be connected in series (2) and a battery (1). Terminal 12), a current detector (3) and a current monitor (6) connected between this terminal (12), the control unit (4) and the voltage monitoring unit (5) connected between the rectifier unit and the battery terminal (12) arranged, the outputs of the voltage monitoring unit (5) and the current monitoring unit (6) are connected and connected to the amplifier input (7) connected to the control input (13) of the throughput unit (2) and the control unit (4) connects to switch (K), relay closing switch (JE) closing parallel to switch (K) contact (s).

FIG. is built. In Fig. 1, the pass-through unit denoted by 2 consists of two current currents: (21) forward and (22) return. In the forward current path (21), a thyristor (TH) is provided, the ignition circuit of the thyristor (TH) being constructed of resistors (R3, R4 and R5), transistor (T2) and diode (D4). A current sensor (RS) measuring resistor is inserted between the rectifier unit (1) and the terminal (12) in the return current path (22). The voltage monitoring unit (5) in the example is a potentiometer (P4) with a slider (D7) connected to a diode anode. Amplifier (7) consists of transistor (T3), resistor (R6) and diode (D5). The current monitor (6) consists of a diode (D6) connected to a more positive potential terminal (31) during operation of the measuring resistor (RS), and a capacitor (C3) and a potentiometer (P3) connected to a negative terminal terminal (32).

The control unit (4) is based on an operating amplifier (ICI) connected as a comparator, the input of which is the Zener diode (Zl), the resistor (R1) and the potentiometer (P1) which determines the comparator, and its output is connected via Transistor (TI) in which the relay (J) is arranged in a collector circuit. The switching of the control unit (4) is further completed by the potentiometer (P2), the protective diode (D1, D2, D3) and the filter capacitor (C1 and C2).

The operation of the exemplary current-controlled battery charger is as follows. Assuming that the rechargeable battery connected to terminal (12) is not discharged, the relay (J) is plugged in and (JE) is connected to AC power. The charging process starts with the mean value of the charging current set using the potentiometer (P3) in the current monitor (6). Through the thyristor (TH), current pulses of a width corresponding to the ignition delay set by the amplifier (7) flow into the battery. These charging current pulses also flow through the current sensor (3) causing a voltage drop across it. The voltage difference between the terminals of the current sensor (3) is reduced to the capacitor (C3) by reducing the voltage of the diode (D6) to the capacitor (C3) when its voltage is less than that of the current sensor (3). This latter condition is a condition for opening the diode (D6), the diode (D6) otherwise disconnecting the capacitor (C3) from the current sensor (3). By the process described, current feedback is generated from the charging current.

The higher the voltage of the capacitor (C3), e.g. due to the higher charge current due to the increase in the mains voltage, the higher the collector current of the transistor (T3). As a result, the transistor (T2) receives less base current, so that the thyristor ignition can occur only later, i.e. the average charge current does not increase.

As the charging process progresses, the opposite regulatory process takes place. The terminal voltage of the battery increases, thus reducing the magnitude of the charging current pulses. As a result, capacitor (C3) is charged to a lower voltage, transistor (T3) opens less, collector current is reduced. The transistor (T2) receives more base currents, so that the thyristor ignition time is shifted forward in time, and the average charge current does not decrease.

The voltage monitoring unit (5) is activated only when the battery terminal voltage reaches a predetermined value, which is a maximum of 2.4 V per cell for the start of the increased sparkling of the electrolyte. Then, with the help of amplifier (7), a strong control of the charging current begins, and finally, when the control unit (4) allows it, the transistor (T3) opens so much that the transistor (T2) can no longer ignite the thyristor (TH), and the charging current is thus eliminated. At this point, the battery cell voltage is 2.75 V.

However, the control unit (4) is already lower than the cell voltage, e.g. At 2.6 V, the charger is disconnected from the AC outlet. The split terminal voltage of the battery is displayed on the slider of the potentiometer (P1), and when this voltage exceeds the reference voltage defined by the Zener diode (Zl), the operation amplifier acting as a comparator (ICI) turns over, transistor (TI) turns off and J) relay release. After this, if the battery voltage, eg. due to self-discharge, to a predetermined value, e.g. decreases to 2.1 V per cell, the comparator tilts, the transistor (TI) turns on, the relay (J) pulls, and the battery charger reconnects. The potentiometer (P2) is involved in adjusting the hysteresis and tilt levels of the comparator.

Thus, the battery charger according to the invention is capable of controlling the charging current during charging by simple means of charging the battery with current pulses, optionally regulating the charging current at the end of the charging process, depending on the terminal voltage of the battery, and depending on the terminal voltage of the battery.

EN 207 618 Β and on. Thus, it is advantageous for partially restoring the original amperage capacity of sulphate batteries, or for batteries that are permanently out of service, e.g. for unattended charging and maintenance of batteries of agricultural machines that have been shut down for winter.

During experiments with the exemplary battery charger, it was observed that the charge current consisted of a series of larger and smaller current pulses of varying magnitude, alternating each other, while the charger functioned normally, without oscillation. Amperor capacitance tests under controlled conditions have shown that batteries charged in this manner have been surprisingly regenerated.

Claims (2)

PATENT CLAIMS A current regulator battery charger comprising a rectifier unit (1) connected to an AC mains terminal (11), preferably via one or more circuit breakers (K), a series throughput unit (2) and a battery terminal terminal (12) , a current sensor (3), which may be connected between the control unit (4) and / or voltage monitoring unit (5) connected to this terminal (12), the rectifier unit (1) and the terminal (12) suitable for connecting the battery, a current monitor (6) is provided, the output of the current monitor (6) is connected to the input of an amplifier (7), the output of the amplifier (7) is connected to the control input (13) of the bypass unit (2) (7) is also connected to the regulator input (13) of the throughput unit (2), the controller and the firing unit (4) is connected to the switch (K) by means of a relay closing contact (s) (JE) which bridges the switch (K) in parallel, characterized in that the current monitor (6) is a peak rectifier with a variable output resistor. the input of the peak rectifier is the input of the current monitor) and the output of the peak rectifier is the output of the current monitor (6). A current regulator battery charger according to claim 1, characterized in that one of the two terminals of the current sensor (3) is connected to a more positive terminal during operation by an anode of a diode (D6) and a capacitor (32) of a negative current potential. One terminal (C3) and potentiometer (P3) are connected, the cathode of the diode (D6) and the other terminal of the capacitor (C3) and potentiometer (P3) are connected and connected to the input of the amplifier (7).