RU80289U1 - BATTERY CHARGER - Google Patents

Abstract

A battery charger can be used to charge acidic or alkaline batteries from an alternating current source with a zero output. The battery charger includes a mains power supply, a thyristor, and a thyristor control circuit. The control circuit includes a ballast resistor, a timing RC circuit, a zener diode, and a terminating resistor connected in series. The phase output of the mains power supply is connected to the positive lining of the battery through a fuse, an adjustable resistor and a thyristor. The negative lining of the battery is connected to the zero terminal of the mains power supply. The ballast resistor, the timing resistor and the timing capacitor of the RC circuit are connected in series and connected between the phase and zero terminals of the mains power supply. The midpoint of the RC chain is connected to a zener diode. The thyristor control electrode is connected to a limiting resistor. The thyristor cathode is combined with the zero output of the mains power supply. The thyristor anode through an adjustable resistor and fuse is connected to the phase output of the power source. The resistance of the charging and timing resistors and the capacitance of the capacitor are selected based on the charge time of the battery in the range of 7 ÷ 10 ms. The charger provides charging of the battery in the falling section of the sine wave of the rectified voltage, thereby eliminating the high input voltage of the battery. The result is increased reliability. 1 n.a. P. f-ly, 2 ill.

Description

The utility model relates to the field of electrical engineering, and more specifically to devices for charging batteries and rechargeable batteries from an alternating current main with a zero output, and can be used to charge acid or alkaline batteries, in particular for automobile transport.

Chargers are based mainly on the use of a transformer that lowers the mains voltage of 220 V 50 Hz to the required voltage of 13 ÷ 18 V. Charger-rectifier devices for industrial purposes, electric power facilities and the oil and gas complex of the NRT series, made according to the principle of a controlled diode-thyristor converter, are known AC to DC (information on the Internet site at: http://www.promspravka.com/catalog). These charging and rectifying devices have a voltage transformer at the input, and an LC filter at the output. The battery is charged and recharged at constant voltage. The disadvantages of the HPT series devices include large weight and size indicators. They are due to the presence in the circuit of a low-frequency (50 Hz) transformer, which ensures coordination of the mains voltage with the voltage necessary for the charge and has a relatively large mass and dimensions.

Known chargers using transformerless rectifiers at the input, for example: 1. Charger according to the patent of the Russian Federation for invention No. 2222073, IPC H02J 7/10; 2. A power source for charging batteries, published on p.530 of the publication "Integrated circuits: Microcircuits for switching power supplies and their application. 2nd Edition. - M .: DODEKA, 2000. - 608 p. ". AT

These known chargers [1, 2] use a rectifier designed to rectify the mains voltage of 220 V 50 Hz into a constant voltage and further convert the rectified voltage into the required low-voltage constant voltage. For this, a transformer and an output rectifier are installed at the output of the device. Thus, a power source for charging batteries [2] contains an input rectifier connected to an AC network, an input filter element connected in parallel with the output of the rectifier, a current-sensing element connected to one of the inputs of the control device, a flyback transformer, a key element, an output rectifier, and an output filter element. The key element is connected in series with the current-sensing element and the primary winding of the transformer. The secondary winding of the transformer through the output rectifier is connected to the battery. An additional feedback winding of the transformer is connected to a control device, the output of which is connected to a key element. Energy transfer in such a source occurs when the key element is turned off. However, due to the presence of an output transformer in the circuit, the device also has oversized dimensions.

Transformerless chargers with controlled rectifiers, half-wave or half-wave are also known in the art. The device for charging the battery according to the patent of the Russian Federation for the invention No. 2269843, IPC H02J 7/02, H02M 10/44, contains a half-wave bridge rectifier on thyristors, two current-limiting inductors connected between the same-polar terminals of the output terminals of the bridge and the terminals of the battery two-section battery, and a thyristor monitoring and control unit. The midpoint of the two-cell battery is connected to one of the terminals of the input diagonal of the bridge through a key

bilateral conductivity. In one cycle of each half-cycle, the current of the alternating current source in one of the inductive coils stores excess energy, which in the next cycle is transferred to the battery. And the battery charge at this time is produced by the energy stored in another inductive coil. The presence of two inductive coils improves the technical and economic characteristics of the charge device, but increases its dimensions. In addition, experts in the field of electrical engineering know that in the inductors there are energy losses that are the sum of the losses in the wires, dielectric and core. To reduce losses, it is often necessary to increase the size of the coil. And this, in turn, increases the overall dimensions of the device.

Closest to the claimed utility model is a battery charge device with a half-wave rectifier (USSR author's certificate No. 1129675, IPC H02J 7/10). It contains a transistor voltage regulator of three transistors, connected between the energy source and the rechargeable battery and simultaneously performing the function of a rectifier. The control input of the transistor regulator is connected to a control circuit that includes a reference voltage source, a first zener diode with a shunt circuit connected between the reference voltage source and the voltage regulator, and RC timing circuits. The reference voltage source is connected to the terminals of the energy source and consists of a zener diode (second) connected in series and two charging (ballast) resistors. The positive terminal of the zener diode of the reference voltage source is connected to the negative terminal of the power source. When voltage is applied from the power source, a lower voltage level is formed in the charger that is acceptable for a long battery charge,

and the upper level of voltage limitation on the battery during its pulse charge. For temperature stabilization and regulation within certain limits of the voltage level at the control input of the transistor regulator, the circuit of the device includes a circuit shunting the battery and consisting of a series-connected diode and two resistors (one adjustable), the middle point of which is connected to the emitter of the first transistor. A diode is connected between the reference voltage source and the voltage regulator, which performs the function of protecting against short circuits and eliminates the influence of voltage fluctuations of the power source on the reference voltage source. The device according to the prototype reliably functions and at the same time has lower mass and size indicators in comparison with previous analogues. The disadvantages include the prolonged formation of a pulsed charge mode, which ultimately increases the battery charge time. In addition, for the formation of a charge, many semiconductor elements are included in the device circuit, which in turn complicates the circuit and reduces the reliability of the charger.

The objective of the utility model is to create a simple, small-sized and reliable transformerless charger.

The technical result obtained by the implementation of the proposed charger and aimed at solving the problem is to ensure that the battery is charged on the incident section of the rectified voltage sinusoid (reverse sinusoidal rectified voltage) and thereby eliminates the supply of high input voltage to the battery, leading to the occurrence of abnormal modes.

The technical result is achieved as follows.

Like the prototype, the battery charger claimed as a utility model contains a mains power supply, a protection element, a rectifier, an adjustable resistor connected to the rectifier, a control circuit connected to the control input of the rectifier and including a ballast resistor, a timing RC circuit and connected in series between themselves a zener diode and a limiting resistor. In contrast to the prototype, a thyristor was used as a rectifier, and a fuse was used as a protection element. The phase output of the mains power supply is connected to the positive battery lining through a fuse, an adjustable resistor and a thyristor, and the negative battery lining is connected to the zero output of the mains power supply. The ballast resistor, the timing resistor and the timing capacitor of the RC circuit are connected in series and connected between the phase and zero terminals of the mains power supply. The midpoint of the RC circuit is connected through a zener diode and a limiting resistor to the thyristor control electrode, the cathode of which is combined with the zero output of the mains power supply, and the anode is connected to the phase output of the power supply through an adjustable resistor and fuse. The resistance of the ballast and timing resistors and the capacitance of the capacitor are selected in accordance with the charge time of the battery in the range of 7 ÷ 10 ms according to the formula:

T = (R ₅ + R ₆ ) C, where

T is the charge constant (capacitor charge time);

R ₅ is the resistance of the ballast resistor;

R ₆ is the resistance of the timing resistor;

C is the capacity of the timing capacitor.

The proposed set of features characterizing the claimed utility model, among the known technical solutions is not

detected. This confirms the novelty of the claimed charger.

The use of a thyristor as a rectifier and the proposed control circuit can significantly simplify the charger circuit and reduce its overall dimensions. By selecting the resistance of the time-setting resistor, it is possible to achieve the desired limits for regulating the charge time of the battery and the output voltage required to charge the battery.

Figure 1 shows a diagram of the inventive charging device, and figure 2 shows the dependence of the rectified and charging voltage on the charge time of the capacitor. The shaded area in figure 2 corresponds to the charge region of the battery, where U _op is the charging voltage of the battery.

The battery charger is connected to a power source 1 of 220 V 50 Hz and contains a fuse 2, an adjustable resistor 3, a thyristor 4, a ballast resistor 5, a timing RC circuit from a timing resistor 6 and a timing capacitor 7, a zener diode 8, a limiting resistor 9 Position 10 in figure 1 indicates the battery.

The battery charger is as follows.

When the charger is turned on and the supply voltage is supplied from the network source 1, the phase starts to work, which has a larger positive half-wave at a given time. At the beginning of the positive half-cycle, thyristor 4 is closed. As the mains voltage increases, the charge-generating capacitor 7 is charged along the circuit: “+” of the power supply 1, ballast resistor 5, the timing-resistor 6, “+” of the capacitor 7 and “-” the power supply (Fig. 1). The increase in voltage across the capacitor 7 lags behind the mains voltage by an amount depending on the total

the resistance of the resistors 5, 6 and the capacitance of the capacitor 7. The charge of the capacitor 7 continues until the voltage on it reaches the value necessary to turn on the zener diode 8 and, accordingly, the voltage sufficient to open the thyristor 4. The control of the output rectified voltage is reduced to control over time when thyristor 4 is turned on. The charge constant of the capacitor 7 is selected based on the resistances of the resistors 5, 6 and the capacitance of the capacitor 7 according to the formula:

T = (K ₅ + K ₆ ) C, where

T is the charge constant (capacitor charge time);

R ₅ is the resistance of the ballast resistor;

R ₆ is the resistance of the timing resistor;

C is the capacity of the timing capacitor. By selecting the resistance of the timing resistor 6, it is possible to achieve the desired limits for regulating the charge time of the battery 10, that is, in the range of 7 ÷ 10 ms (FIG. 2), which corresponds to the decaying part of the voltage sine wave, and regulating the output voltage required to charge the battery 10. Changing the slope of the direct charge (figure 2) using an adjustable resistor 3, it is possible to turn on the zener diode 8 and, accordingly, the thyristor 4 in the range from 17 to 10 V, providing a charge of the battery 10 at a decreasing part of the sine wave. Consequently, there is no need to use electromagnetic devices in the charger circuit. This means that the high voltage supplied to the charge of the battery 10 is eliminated. Thereby, the reliability of the charger is increased and its mass-dimensional indicators are improved. Thyristor 4 remains open until the end of the half-cycle and is locked when the current passes through zero and the polarity changes. The next turn on of the thyristor 4 will occur when the capacitor 7 is completely discharged. Fuse 2 is used to turn off the circuit when

the occurrence of abnormal modes and is more reliable than a diode that performs the function of protecting against short circuits of the prototype charger. Zener diode 8 serves to stabilize the turn-on voltage of the thyristor 4, since any fluctuations in the voltage of the network change within the same range the value of the rectified voltage, violating and worsening the battery charge mode. The limiting resistor 9 serves to limit the discharge current of the capacitor 7 when the zener diode 8 is broken and the thyristor 4 is turned on at a voltage corresponding to the charge voltage of the battery 10. An adjustable resistor 3 serves to limit the charge current of the battery 10. Using the electronic charge circuit, the capacitor 7 can provide output reliable battery charging method 10.

Claims (1)

A battery charger containing a power supply, a protection element, a rectifier, an adjustable resistor connected to the rectifier, a control circuit connected to the control input of the rectifier and including a ballast resistor, a timing RC circuit, and a zener diode and a limiting resistor connected in series, characterized in that a thyristor is used as a rectifier, a fuse is used as a protection element, while the phase output of the power supply source is niya is connected to the positive battery lining through a fuse, an adjustable resistor and a thyristor, and the negative battery lining is connected to the zero output of the mains power supply, in addition, the ballast resistor, the timing resistor and the timing capacitor of the RC circuit are connected in series and are connected between phase and zero the outputs of the mains power supply, the midpoint of the RC circuit is connected through a zener diode and a limiting resistor to the thyristor control electrode, the cathode which is combined with the zero output of the mains power supply, and the anode through an adjustable resistor and fuse is connected to the phase output of the power supply, and the resistance of the ballast and timing resistors and capacitor capacitance are selected according to the battery charge time from 7 to 10 ms according to the formula: T = (R ₅ + R ₆ ) C, where T is the charge constant (capacitor charge time); R ₅ is the resistance of the ballast resistor; R ₆ is the resistance of the timing resistor; C is the capacity of the timing capacitor.