RU112443U1 - POWER SUPPLY - Google Patents

Abstract

A power supply unit containing a comparison device, first and second transistors, inductance, a current sensor, while the first output of the comparison device is electrically connected to the control terminal of the first transistor, the second output of the comparator is electrically connected to the control terminal of the second transistor, the first power terminals of the first and second transistors and the first inductance terminal is electrically connected to each other, the second power terminals of the first and second transistors are designed to supply a constant voltage, the first input of the comparison device is electrically connected to the output of the current sensor, the input of which and the second inductance terminal are intended for electrical connection with the load, characterized in that contains a constant and two variable resistors and a switch, while the first terminals of the constant and first variable resistors are electrically connected to each other, the second terminals of the constant and first variable resistors and the first power terminal of the switch are designed to supply a constant voltage, the second power terminal of the switch and the first terminal of the second variable resistor are electrically connected to each other, the third terminal of the first variable resistor, as well as the second and third terminals of the second variable resistor are electrically connected to the second input of the comparison device.

Description

The utility model relates to power electronics, in particular to power sources, and can be used to create laser power sources.

Known battery charger [1] (power supply), containing a comparison device, the first and second transistors, inductance, current sensor, which is used as a resistor. The first output of the comparison device is electrically connected to the control terminal of the first transistor, the second output of the comparison device is electrically connected to the control terminal of the second transistor, and the input is electrically connected to the output of the current sensor. The first power terminals of the first and second transistors and the first inductance terminal are electrically connected to each other, the second power terminals of the first and second transistors are designed to supply power. The second inductance terminal is electrically connected to the first terminal of the current sensor, the second terminal of which is electrically connected to the first terminal of the rechargeable battery, the second terminal of which is electrically connected to the ground bus.

Due to the fact that the current sensor is located in the electric circuit between the inductance and the rechargeable battery, to supply a signal from the current sensor to the input of the comparison device, it is necessary to have two connecting conductors, which is not always convenient, for example, in cases where the dimensions are significant .

The closest in technical essence to the claimed device is a power supply (hereinafter - PSU) [2], containing a comparison device, the first and second transistors, inductance, current sensor, which is used as a resistor. The first output of the comparison device is electrically connected to the control terminal of the first transistor, the second output of the comparison device is electrically connected to the control terminal of the second transistor, the first power terminals of the first and second transistors and the first inductance terminal are electrically connected, the second power terminals of the first and second transistors supply voltage, while the second terminal of the inductance is electrically connected to the first terminal of the load, the second terminal of which is electrically connected to Odom current sensor, whose output is electrically connected to the input of the comparator.

As a current sensor, a resistor is used, the first terminal of which is electrically connected to the second terminal of the load, the second terminal of the resistor is electrically connected to the earth bus.

Due to the fact that the resistor is in the electric circuit between the load and the ground bus, only one conductor is needed to supply a signal from this resistor to the input of the comparison device.

However, when testing the load with the power supply turned on, the indicated PSU [2] provides the rated load current with significant power consumption, which is not required at all.

The objective of this utility model is to reduce the power consumption of the PSU during load testing with the power supply turned on.

The essence of the utility model is that a power supply unit containing a comparison device, first and second transistors, an inductance, a current sensor, wherein the first output of the comparison device is electrically connected to the control terminal of the first transistor, the second output of the comparison device is electrically connected to the control terminal of the second transistor , the first power terminals of the first and second transistors and the first inductance terminal are electrically connected, the second power terminals of the first and second transistors are intended to supply a constant voltage, the first input of the comparison device is electrically connected to the output of the current sensor, the input of which and the second inductance terminal are designed for electrical communication with the load, unlike the prototype, it contains a constant and two variable resistors and a key, while the first conclusions of the constant and first alternating resistors are electrically connected, the second terminals of the constant and first alternating resistors and the first power terminal of the key are designed to supply constant voltage, the second power output key and the first terminal of the second variable resistor electrically connected between a third terminal of the first variable resistor, and the second and third terminals of the second variable resistor electrically connected with the second input of the comparator.

Introduction to the power supply of a constant and two variable resistors and a key, the presence of electrical communication between the first terminals of the constant and first variable resistors, the purpose for supplying a constant voltage of the second terminals of the constant and first variable resistors and the first power output of the key, the presence of electrical communication between the second power output key and the first output of the second variable resistor, the presence of electrical communication of the third output of the first variable resistor, as well as the second and third output of the second variable resistor with a second input of the comparison device, to reduce the voltage (as compared with the operating voltage) to the second input of comparator PD during load testing with incorporated power unit.

Since the voltage supplied to the second input of the comparison device is used in the comparison device as a reference comparison signal for the signal supplied to the first input of the comparison device from the output of the current sensor, the voltage at the second input of the power supply comparison device decreases when testing the load with the power supply turned on leads to a decrease in the power supply current through the load.

The possible use of a resistor as a current sensor can simplify the power supply circuit.

The utility model is illustrated by a figure.

The figure shows a functional diagram of the PSU.

The PSU contains a comparison device 1, the first and second transistors 2 and 3, respectively, the inductance 4, the current sensor 5, which is used as a resistor, a constant 6, as well as the first 7 and second 8 variable resistors, respectively, and a key 9. Perhaps another embodiment of the current sensor 5, for example, using a Hall sensor.

Comparison device 1 is made on the IR2104SPBF, LM397MF and LMC7101AIM5 microcircuits and is intended to compare the signal supplied to the first input of the comparison device with the reference signal supplied to the second input of the comparison device and to issue control signals to the control terminals of the first 2 and second 3 transistors .

The first 2 and second 3 transistors type IRF1104PBF are used in key mode.

As inductance 4, a choke with an inductance of about 100 μH was used.

As a current sensor 5, a resistor OAR1-R010FI is used.

A resistor P1-12-0.25-24 kOhm ± 5% - M-A was used as a constant resistor 6, and 3362P-1-103LF resistors (10 kOhm) were used as variable resistors 7 and 8. As the key 9 used transistor FMMT491A.

The first output of the comparison device 1 is electrically connected to the control terminal of the first transistor 2, the second output of the comparison device 1 is electrically connected to the control terminal of the second transistor 3.

The first input of the comparison device 1 is electrically connected to the output of the current sensor 5.

The first power terminals of the first 2 and second 3 transistors and the first terminal of the inductance 4 are electrically connected, and the second power terminals of the first 2 and second 3 transistors are designed to supply a constant voltage U.

The first terminals of the constant 6 and the first alternating 7 resistors are electrically connected, the second terminals of the constant 6 and the first alternating 7 resistors and the first power output of the key 9 are designed to supply constant voltage, the second output of the key 9 and the first output of the second alternating 8 resistor are electrically connected itself, the third terminal of the first variable 7 resistor, as well as the second and third terminals of the second alternating 8 resistor, are electrically connected to the second input of the comparison device 1.

The input of the current sensor 5 and the second output of the inductance 4 are intended for electrical communication with the load 10, which is used as a laser diode.

BP works as follows.

Consider first the operation of the power supply in the operating mode when the key 9 is closed. Then the voltage at the second input of the comparison device 1 is constant and is determined by a constant voltage U ₀ and a resistive divider composed of a constant resistor 6 and a variable resistor 7.

Consider the point in time when the signal from the current sensor 5 at the first input of the comparison device 1 is less than the signal at the second input of the comparison device 1.

In this case, the comparison device 1 from the first output gives a signal to open the first transistor 2 to the control terminal of the first transistor 2 (the second transistor 3 is closed at this time, since there is no signal at the second output of the comparison device 1). The current from the power source increases through the transistor 2, inductance 4, load 10 and current sensor 5. When the maximum threshold value of the current determined by the constant signal from the second input of the comparison device 1 is reached, the comparison device 1 gives a signal to close the first transistor 2 to the control terminal the first transistor 2 and at the same time a signal to open the second transistor 3 to the control terminal of the second transistor 3. The first transistor 2 closes and the second transistor 3 opens. By closing the first transistor 2 and opening the second transistor 3, the inductance 4 maintains a decreasing current through the load 10 and through the second transistor 3. The current flowing through the current sensor 5 decreases, and when the minimum threshold value of the current, also determined by a constant signal from the second input of the device, is reached comparison 1, the comparison device 1 sends a signal to open the first transistor 2 to the control terminal of the first transistor 2 and at the same time a signal to close the second transistor 3 to the control terminal in of the second transistor 3. The first transistor 2 (the second transistor 3 is closed at this time) opens, and the current from the power source flows increasing through the first transistor 2, inductance 4, load 10 and current sensor 5. When the maximum threshold current value is reached, the comparison device 1 supplies a signal to close the first transistor 2 to the control terminal of the first transistor 2 and at the same time a signal to open the second transistor 3 to the control terminal of the second transistor 3.

Thus, in the steady state, the current flowing through the load 10 and the current sensor 5, periodically with a frequency of about 20 kHz, rises to the maximum threshold value (determined by the constant voltage at the second input of the comparison device 1) and drops to the minimum threshold value (also determined by the constant voltage at the second input of the comparison device 1).

Now consider the operation of the PSU in load test mode 10 with the power supply turned on.

When testing load 10 with the PSU turned on, a signal is opened to the control output of key 9, which opens key 9. When opening the key 9, the second variable resistor 8 shunts the first variable resistor 7. The voltage supplied to the second input of the comparison device 1 from the third output of the variable resistor 7 , forming together with a constant resistor 6 a resistive divider, to which a constant voltage U _{0 is} applied, decreases. Since the voltage value at the second input of the comparison device 1 determines the maximum and minimum threshold value of the load current 10, these threshold values of the load current 10 are reduced, respectively, the power consumption of the power supply is reduced.

Thus, a reduction in power consumption of the PSU is provided during load testing with the power supply turned on.

Information sources.

1.http: //www.farnell.com/datasheets/77082.pdf.-Adjustable-output, switch-mode current source with synchronous rectifier. - Page 7, fig.2b.

2. http://www.farnell.com/datasheets/77082.pdf.-Adjustable-output, switch-mode current source with synchronous rectifier. - Page 7, fig.2a. - prototype.

Claims (1)

A power supply unit comprising a comparison device, first and second transistors, an inductance, a current sensor, wherein the first output of the comparison device is electrically connected to the control terminal of the first transistor, the second output of the comparison device is electrically connected to the control terminal of the second transistor, the first power terminals of the first and second transistors and the first inductance terminal is electrically connected, the second power terminals of the first and second transistors are designed to supply a constant voltage, the first input the comparison device is electrically connected to the output of the current sensor, the input of which and the second inductance terminal are designed for electrical communication with the load, characterized in that it contains a constant and two variable resistors and a key, while the first terminals of the constant and first variable resistors are electrically connected, the second the terminals of the constant and first variable resistors and the first power terminal of the switch are for supplying constant voltage, the second power terminal of the switch and the first terminal of the second alternating The resistors are electrically connected, the third terminal of the first variable resistor, as well as the second and third terminals of the second variable resistor, are electrically connected to the second input of the comparison device.