RU2513902C1 - Switched mode power supply unit - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: switched mode power supply unit contains a pulse-width modulator, a switching-type transistor for voltage converter, an accumulator battery, two analogue-to-digital converters, three comparator modules and three sources of threshold voltage, a frequency selection module of the pulse-width modulator, a module shaping a command to stop chargeor discharge of the accumulator, a current sensor, a normal open relay interconnected as specified in the application materials.

EFFECT: expanding dynamic range of the device operation at increase in optimisation degree of operation modes for its components.

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Description

The invention relates to the field of electrical engineering and can be used in devices for backup or uninterruptible power supply of a direct current network, mainly operating from unstable power sources, the voltage of which can vary widely.

Known switching power supply ELN-60, manufactured by Mean Well, containing a voltage converter comprising a series-connected rectifier with a filter, a power switch, an galvanic isolation element and an output rectifier with a filter, the output of which is the output of the device to which the battery is connected via a charge unit and backup switching, the input of the converter is connected to the mains through a filter, the control input of the power switch is connected to the output of the pulse-width modulator, to the first input to the output of the power switch overload protection unit is plugged in, and its second input, through the optoelectronic isolation, is connected to the output of the detection module connected to the output of the device (istochnik).

In the well-known switching power supply, stabilization of the output voltage, a smooth increase in voltage at start-up, and a mode of skipping PWM pulses at low load are ensured. However, the device has an insufficiently wide range of input voltages, as well as an insufficient degree of optimization of the operating mode of the elements of the device depending on the magnitude of the input voltage.

The technical result of the invention is to expand the dynamic range of the device while increasing the degree of optimization of the modes of operation of its elements.

The technical result is achieved in that in a switching power supply containing a pulse-width modulator unit, the output of which is connected to the control input of the key transistor of the voltage converter, and the battery, the input and output of the voltage converter are the input and output of the device, respectively, according to the invention, two analog -digital converter, three comparison modules, a pulse width modulator frequency selection module and a module for terminating a charge or a battery discharge, while the inputs of the first and second analog-to-digital converters are connected respectively to the input of the device and to the output of the device, the output of the first analog-to-digital converter is connected to the first inputs of the first and third comparison modules and to the first input of the frequency selection module of the pulse-width modulator, the output of the second analog-to-digital converter is connected to the first input of the second comparison module, to the second input of the pulse-width modulator frequency selection module, with the input of voltage pulses ”of a pulse-width modulator unit and with the first input of the module for generating a command to stop charging or discharging the battery, the second inputs of the first, second and third comparison modules are connected to the corresponding threshold voltage sources, and the outputs of the first and third comparison modules are connected to the enable input of a pulse-width modulator, the output of the second comparison module is connected to the input "duration limitation" of the pulse-width modulator, the output of the wide frequency selection module a no-pulse modulator is connected to the input "setting the operating frequency" of the pulse-width modulator unit, the battery is connected to the output of the device with one terminal through a current sensor, and the other terminal through normally open relay contacts connected to the first output of the formation of the command to stop charging or battery discharge, the second output of which is connected to the input "stabilization of the charge current" of the pulse-width modulator unit, the output of the current sensor is connected to the second input of the formation module A team of termination of the charge or discharge the battery.

The voltage converter includes a circuit connected to the input of the voltage converter and consisting of a series-connected inductor and a key transistor, in parallel with which a second inductor is connected through the first capacitor, the connection point of the second inductor and the first capacitor is connected through a diode to the second capacitor connected to voltage converter output.

The drawing shows a diagram of a switching power supply.

The switching power supply contains a pulse-width modulator unit 1, the output of which is connected to the control input of the key transistor of the voltage converter 2, and the battery 3, the input and output of the voltage converter 2 are the input and output of the device, the inputs of the first and second analog-to-digital converters 4 , 5 are connected respectively to the input of the device and to the output of the device, the output of the first analog-to-digital converter 4 is connected to the first inputs of the first and third modules 6, 8 is compared and with the first input of the pulse width modulator frequency selection module 9, the output of the second analog-to-digital converter 5 is connected to the first input of the second comparison module 7, with the second input “frequency selection” of the pulse width modulator frequency selection module 9, with the input “reverse connection of voltage stabilization ”of pulse-width modulator block 1 and with the first input of the module 10 for generating a command to stop the charge or discharge of the battery, the second inputs of the first, second and third comparison modules are connected to the corresponding threshold voltage sources, and the outputs of the first and third comparison modules 6, 8 are connected to the turn-off input of the pulse-width modulator unit 1, the output of the second comparison module 7 is connected to the “duration limitation” input of the pulse-width modulator block 1, the output of the frequency selection module 9 -pulse modulator is connected to the input "setting the operating frequency" of block 1 of the pulse-width modulator, the battery 3 is connected to the output of the device with one terminal through the current sensor 11, and the other through the normal open contacts 12 of the relay 13 connected to the first output of the module 10 forming the command to stop charging or discharging the battery, the second output of which is connected to the input "stabilization of the charge current" of the pulse-width modulator unit 1, the output of the current sensor 11 is connected to the second input of the formation module 10 commands to stop charging or discharging the battery.

The voltage converter 2 includes a circuit connected to the input of the voltage converter and consisting of a series-connected inductor 14 and a key transistor 15, in parallel with which a second inductor 17 is connected through the first capacitor 16, the connection point of the second inductor 17 and the first capacitor 16 through the diode 18 is connected to a second capacitor 19 connected to the output of the voltage converter.

Switching power supply operates as follows.

The voltage supplied to the input of the device, using the first analog-to-digital Converter 4 is converted into digital form and then compared with the set thresholds (U _por1 and U _por2 ) in the first and third comparison modules 6, 8. The voltage at the output of the device using the second analog-to-digital Converter 5 is converted into digital form and compared with the set threshold (U _por3 ) in the second comparison module 7. At the same time, the signal from the output of the second analog-to-digital converter 5 is also fed to the first input of the module 10 for generating a command to terminate the charge or discharge of the battery.

If the voltage level at the input of the device is lower than the threshold value U _por1 (too low for the normal operation of the device), then a signal is generated at the output of the first comparison module 6, which is fed to the turn-off input of block 1 of the pulse-width modulator and prohibits the device from working. After turning off the block 1 of the pulse-width modulator, the voltage at the output of the device quickly decreases, thereby triggering the module 10 generating a command to stop charging or discharging the battery, which includes a relay 13, making contacts 12, through which the battery 3 is connected to the output of the device. A similar process occurs if the input voltage level has exceeded the threshold value U _por2 , i.e. is above the upper limit. Then, at the output of the third comparison module 8, a signal is generated that goes to the turn-off input of the pulse-width modulator unit 1 and prohibits the operation of the device, as a result of which the output voltage decreases and the battery is connected to the device output.

If the input supply voltage is in the operating range of the device (U _por1 <U _slave <U _por2 ), then from the output of the pulse-width modulator frequency selection module 9, the control signal receives the setting of the working frequency of the pulse-width modulator block 1 setting the optimum frequency of the pulse width modulator. The optimal frequency of a pulse-width modulator with fixed parameters of the chokes is determined by the input voltage level. It can be calculated according to the methods for switching power supplies given in the technical literature. At a higher voltage, the frequency of the pulse-width modulator must be higher, otherwise there is a danger of the chokes entering the saturation mode. The optimal choice of frequency for each input voltage level in turn allows you to best select the parameters of the chokes, reduce the number of turns in their windings, increase the overall efficiency of the device and / or expand the range of input voltages.

The duty cycle of the signal at the output of the pulse-width modulator unit 1, which is supplied to the control input of the key transistor 15 of the voltage converter 2, is changed in such a way as to maintain the voltage stabilization feedback of the pulse-width modulator unit 1 at a stable digitized voltage value. In the case of an increase in the load at the output of the device, the duration of the active signal level of the pulse-width modulator increases, but only to a certain limit. If this limit pulse width of the pulse-width modulator is not enough to maintain the nominal voltage at the output of the device, then the output voltage begins to decrease. If the output voltage drops below the set threshold U_por3, then the input "limiting the duration" of block 1 of the pulse-width modulator from the output of the second comparison module 7 receives a signal about the device overload at the output. This leads to a stronger restriction on the maximum allowable duration in block 1 of the pulse-width modulator, which entails a further decrease in the output voltage, etc. In a short time, the duration of the pulses at the output of unit 1 decreases to very small values that cannot harm the circuit elements even with a short circuit at the output of the device.

When removing overload or short circuit at the output of the device, the output voltage begins to increase. The signal carrying information about the voltage increase, through an analog-to-digital Converter 5 is fed to the input "voltage stabilization feedback" unit 1 of the pulse-width modulator. As the voltage increases, the restriction in block 1 on the maximum signal width of the pulse-width modulator decreases, which in turn allows you to continue the voltage increase at the output of the device, which further weakens the duration limit, etc. The process stops when the output voltage reaches the nominal value, and feedback begins to work through the input "voltage stabilization feedback" of unit 1, which maintains the output voltage at the nominal level.

The current sensor 11 and the module 10 of the formation of the command to terminate the charge or discharge of the battery provide the required (normal) operation of the battery in the discharge or charge mode.

If there is external power and when the device is operating, the battery 3 is recharged. Charging the battery 3 takes place in two stages. At the first stage, the battery 3 is charged with direct current. To do this, the rated voltage at the output of the device is reduced (by means of modules 5 and 10) so as to ensure that the battery is charged with almost constant current. When the voltage on the battery reaches about 14.3 V, a transition to the buffer mode of battery operation occurs. In this mode, the device sets the rated voltage 13.5-13.8 V, which is constantly supplied to the battery and maintains it in working condition (Standby battery mode).

If the input voltage is absent, then the load is supplied from the battery through the contacts 12 of the relay 13. The discharge current is controlled by the current sensor 11. If the voltage level at the output of the device drops below 10.5 V, then the module 10 for generating a command to stop charging or discharging the battery using relay 13 disconnects the battery from the output of the device until the external power is turned on or until the battery is replaced with a charged one.

Thus, the proposed device provides a soft start, protection against overloads at the input and output, stabilization of the output voltage and implements the functions of a charger with protection against overloads and from excessive battery discharge.

Claims (2)

1. A switching power supply containing a pulse-width modulator unit, the output of which is connected to the control input of the key transistor of the voltage converter, and the battery, the input and output of the voltage converter are the input and output of the device, characterized in that two analog digital converters, three comparison modules, a pulse-width modulator frequency selection module, and a module for generating a command to stop charging or discharging the battery, while the inputs the first and second analog-to-digital converters are connected respectively to the input of the device and to the output of the device, the output of the first analog-to-digital converter is connected to the first inputs of the first and third comparison modules and to the first input of the frequency selection module of the pulse-width modulator, the output of the second analog-to-digital converter connected to the first input of the second comparison module, with the second input of the pulse-width modulator frequency selection module, with the input “voltage stabilization feedback” of the latitude block no-pulse modulator and with the first input of the module forming the command to stop charging or discharging the battery, the second inputs of the first, second and third comparison modules are connected to the corresponding threshold voltage sources, and the outputs of the first and third comparison modules are connected to the input of the pulse-width modulator block , the output of the second comparison module is connected to the input "duration limitation" of the pulse-width modulator block, the output of the pulse-width modulator frequency selection module is connected n to the input "setting the operating frequency" of the pulse-width modulator unit, the battery is connected to the output of the device with one terminal through a current sensor, and with the other terminal through normally open contacts of the relay connected to the first output of the module for generating a command to stop charging or discharging the battery, the second output of which is connected to the input "stabilization of the charge current" of the pulse-width modulator unit, the output of the current sensor is connected to the second input of the module for forming a command to stop charging or battery row. 2. The switching power supply according to claim 1, characterized in that the voltage Converter includes a circuit connected to the input of the voltage Converter and consisting of series-connected inductors and a key transistor, in parallel through which a second inductor is connected through the first capacitor, the connection point of the second the inductor and the first capacitor through a diode is connected to a second capacitor connected to the output of the voltage Converter.