RU179345U1 - Trigger Generator for High Voltage Input Power Supply - Google Patents

Abstract

The utility model "Start Generator for a power supply with a high voltage input" relates to electrical engineering, in particular to pulse voltage converters, and is intended for use in the development of power supplies with a transformerless input. The technical result of the proposed utility model is to improve electrical and operational characteristics, namely : - in the circuit of the proposed start generator (GZ), the level of the pulse voltage at the drain (collector) of the cell is limited a transistor with a zener diode, and at the power output of a PWM controller microchip with a voltage divider and a zener diode, this solution allows you to include a model of the power supply in the input circuit of a power source with a level of U at least 300-700 V; - the power supply is a voltage converter that generates pulses voltage to turn on and briefly maintain the operation of the power source control circuit, then when the power source is put into operation, after reaching the rated voltage stabilization mode U, the power supply switches off by the power of the optocoupler MOS relay, thus the GB does not affect the level of output voltage ripples; - the GB operation mode is short-term, several seconds, thereby increasing the power supply resource. The technical result is achieved by the fact that in a known device containing a PWM controller chip , first electrolytic capacitor, first resistor, second resistor, third resistor, first ceramic capacitor, fourth resistor, second ceramic capacitor, third ceramic capacitor, four the fourth ceramic capacitor, the fifth resistor, the sixth resistor, a pulse transformer, the key transistor, the seventh resistor are additionally introduced into the device circuit: the first zener diode, the eighth resistor, MOS relay, the ninth resistor, the second zener diode, the tenth resistor, the eleventh resistor, the third zener diode, the second electrolytic capacitor, twelfth resistor, rectifier diode, third electrolytic capacitor.

Description

The utility model relates to electrical engineering, in particular to pulse voltage converters, and is intended for use in the development of power supplies with transformerless input.

When designing power supplies with pulsed voltage converters, it is necessary to solve the circuitry problem of forming a power circuit for a control circuit (SU) with a converter that includes a PWM controller. When switching voltage to the input terminals of the power supply, to start the pulse voltage converter, it is necessary to form the supply voltage of the control system by the voltage converter. This task is complicated if the power source operates from a high-voltage input, for example, from an alternating current voltage of 380 V 50 Hz or from a direct current voltage of at least 300 V. For power supply to the control system with a voltage converter, it is necessary to form a power circuit with a level of 12-18 V During the transient process of switching on the voltage converter, a pulse power of several watts is required to start the control system during a time interval of several microseconds.

A device for active start [1], as well as its modifications, are also described in this reference [1]. A diagram of the active starter is shown in FIG. 1. The input voltage of the power source is fed to the input "U _I " of the active starter - to the voltage divider, assembled on a zener diode 7 and resistors 5, 6. The value of the resistor 5 sets the amount of current flowing through the MOS transistor 8, diode 9, necessary for launch the SU power source. The voltage divider assembled on resistors 5, 6 sets the supply voltage level of the _{control unit} “U _pit.su ” by the source.

By installing a zener diode 7 in the gate circuit of the MOS transistor 8, the voltage level at which the transistor opens is limited. The capacitor 4 is a storage of energy, which should be enough to switch the transistor 8 to the open state. After starting and reaching the nominal operating mode, the power source generates a voltage of "U _ref ". The voltage "U _ref " through the voltage divider, assembled on the resistors 1 and 2, enters the base circuit of the bipolar transistor 3. The transistor 3 opens and shunts the gate circuit of the MOS transistor 8. Thus, the active starter is turned off.

A sign of an analogue that coincides with the essential features of the claimed device is the presence of a zener diode, which limits the voltage level of the MOS transistor, a voltage divider that sets the supply voltage level “U _pit.su ”, and the presence of a circuit disconnecting the active starter.

The disadvantages of the analogue are:

- when the power source is powered from the input voltage, level U _in = 300-700 V, the switching voltage spikes in the drain-source circuit of the MOS transistor 8 can reach 2U _in , and therefore exceed the permissible drain-source voltage level of the MOS transistor of the active device start up. When the power source reaches the rated operating mode, the elements of the active start circuit (Fig. 1) remain at the input voltage potential of "U _I ". This will require introducing into the circuit a circuit limiting the voltage surge between the drain and the source of the MOS transistor 8. Thus, with an increase in the input voltage level “U _I ”, the dimensions of the elements of the active starter circuit will increase, and the reliability of the device will decrease;

- to ensure that the SU is started by the power source in operation when the input voltage is applied to the input terminals of the power source, it is necessary to provide a pulse current of at least 1 A in the power circuit of the SU “U _pitssu ” (Fig. 1). This will require an increase in the power and dimensions of the resistors 5, 6;

- the inability to use in pulsed power supplies, SU which is included relative to the potential of the output voltage "-U _o ".

Considered power supplies are characterized by the fact that the SU pulse switching voltage is included in the source circuit relative to the bus "-U _o ". Step-down stabilized voltage converters, both AC / DC-type and DC / DC-type, are often built on this structure. The active starter generates a supply voltage for the SU version, which is connected relative to the “-U _in " bus.

The development of a start-up generator (GZ) for a power supply with a high-voltage input solves the problem of switching on power supplies built according to various structural and functional schemes, including that shown in FIG. 2.

The power supply provides power supply to the control system of the source for a time interval from applying voltage to the input terminals “U _in ” until the output voltage “U _out ” of the source of a given level is formed.

When developing the electrical circuit diagram of the GZ, the prototype was taken to be a typical circuit for switching on the 1114ЕУ7У АЕЯР.431000.379-01 ТУ microcircuit manufactured by NPP Eltom JSC (Tomilino) [2]. The prototype diagram is shown in FIG. 3. The prototype is a pulsed single-cycle voltage converter. The voltage converter circuit is built on a microcircuit of a PWM controller 10, a pulse transformer 15 and a transistor 16 operating in a key mode.

The input voltage “+ U _in ” is supplied to the upper terminal of the primary winding of the pulse transformer, the positive terminal of the input electrolytic capacitor 1 and to the terminal “U _ss ” of the power circuit of the PWM controller 10. An external feedback signal “U _os ” is supplied to the first terminal of the resistor 2 The second terminal of resistor 2 is connected to the first terminal of resistor 3, the first terminal of resistor 4, the first terminal of capacitor 7 and the terminal “U _fb ” of the feedback circuit of the PWM controller. The “COMR” terminal of the PWM controller error signal amplifier is connected to the second terminal of the resistor 4 and the second terminal of the capacitor 7. The “U _ref ” terminal of the PWM controller reference circuit is connected to the first terminal of the resistor 6 and the first terminal of capacitor 5. Terminal “R _t / C _t "PWM controller is connected to the second terminal of the resistor 6 and to the first terminal of the capacitor 8. The input signal" external synchronization "is connected to the second terminal of the capacitor 8 and to the first terminal of the resistor 9.

The output "OUT" of the power output of the PWM controller is connected to the first output of the resistor 13 and the cathode of the diode 11. The output "Isen" of the current feedback circuit of the PWM controller is connected to the first output of the resistor 14, the first output of the capacitor 12 and the anode of the diode 11. Second output the resistor 13 is connected to the gate of the key transistor 16. The second output of the resistor 14 is connected to the first output of the resistor 17 and the source of the key transistor 16. The drain of the key transistor 16 is connected to the lower terminal of the primary winding of the pulse transformer. The “GND” pin of the PWM controller is connected to the negative terminal of the electrolytic capacitor 1, the second terminals of the resistors 3, 9, 17, with the second terminals of the capacitors 5, 12 and the terminal of the negative input voltage potential “-U _in ”. The operation of the considered single ended voltage converter controls the PWM controller chip 10. The input power supply voltage U supplied to the contact _Rin «U _ss" PWM controller. The voltage regulator, which is part of the PWM controller, generates a reference voltage to power the sawtooth generator and comes to the "U _ref " output.

The frequency of the sawtooth generator is determined by the formula:

,

,

in which frequency-setting elements: resistor R _t (kOhm); capacitor C _t (μF) correspond to the elements in FIG. 3 - resistor 6 and capacitor 8.

The feedback signal “U _OS ” is fed to the output “U _fb ” of the PWM controller through a voltage divider assembled on resistors 2, 3. At the output of the PWM controller “OUT”, a pulse train is formed in the form of a meander. The pulse frequency is set by the sawtooth generator, which is part of the PWM controller 10. The pulse duration varies depending on the signal level in the feedback circuit "U _OS ". The pulse sequence is fed to the gate of the transistor 16, operating in key mode. The value of the resistor 13 sets the transition time of the transistor 16 in the on state. A diode 11 is included in the gate circuit of the transistor 16 to reduce the transition time of the transistor 16 to the closed state. Resistor 17 performs the function of a current sensor in the source circuit of transistor 16. The signal from the current sensor (voltage drop across resistor 17) is fed to the Isen output of the PWM controller.

With increasing voltage drop across the resistor 17, the duration of the output pulses of the PWM controller gradually decreases. When switching the key transistor 16 in the primary circuit, an alternating voltage is generated by the frequency specified by the PWM controller generator and the voltage level, which is set by the voltage U _I and the duty cycle of the pulse sequence at the “OUT” output of the PWM controller 10. In the secondary winding of the pulse transformer 15 is formed alternating voltage, the value of which is set by the transformation coefficient.

The disadvantages of the prototype are:

- the operation of a single-cycle voltage converter is characterized by the fact that at the moment the transistor goes to the closed state, a surge voltage is generated on the drain (collector) of the key transistor with a level of about 2U _in , therefore, the GB made according to the structural diagram based on FIG. 3, can not be used in power supplies with high voltage input;

- the pulse voltage converter used as part of the power supply is an additional source of electromagnetic interference, which is undesirable for consumer equipment sensitive to high-frequency harmonics;

- due to the fact that the operation mode of the pulse voltage converter is long and continuous, the resource of the power supply is reduced.

When developing a power supply for a power source with an input voltage of at least 300-700 V, the prototype circuit is taken as the basis for development. When working as part of a DC / DC voltage converter, the power supply is installed directly in the input circuit of the power source after the input filter. When operating as part of an AC / DC voltage converter, the power supply is installed after the input rectifier of the power source. The power supply must be switched on when switching the supply voltage to the input terminals of the power supply. A diagram of the proposed generator model for starting a power supply with a high voltage input is shown in FIG. four.

The technical result of the proposed utility model is to improve the electrical and operational characteristics of the typical circuit diagram for switching on the 1114ЕУ7У АЕЯР.431000.379-01 TU microcircuit, namely:

- in the circuit of the proposed GZ, the level of the pulse voltage at the drain (collector) of the key transistor is limited with the help of a zener diode, and at the power output U _{ss of} a PWM controller chip - with the help of a voltage divider and a zener diode, this solution allows you to include the GZ model in the input circuit of the power supply with level of U _input not less than 300-700 V;

- GZ is a voltage converter that generates voltage pulses for switching on and short-term maintenance of the control system by the power source, then when the power source is started (Fig. 2) into operation, after reaching the rated voltage stabilization mode U _o , the GZ is switched off using an optocoupler MOS the relay, so the mains supply does not affect the level of ripple of the output voltage;

- GZ operation mode is short-term, several seconds, due to which the resource of the power supply increases.

The specified technical result is achieved by the fact that in the known device containing the PWM controller chip, the first electrolytic capacitor, the first resistor, the second resistor, the third resistor, the first ceramic capacitor, the fourth resistor, the second ceramic capacitor, the third ceramic capacitor, the fourth ceramic capacitor, fifth resistor, sixth resistor, pulse transformer, key transistor, seventh resistor, positive terminal of the first electrolytic capacitor connected to the terminal at the “U _ss ” PWM controller, the common point between the first, second, third resistor and the second ceramic capacitor is connected to the output of the “U _fb ” PWM controller, the second terminals of the third resistor and the second ceramic capacitor are connected to the output of the COMR of the PWM controller , the common point between the first ceramic capacitor and the fourth resistor is connected to the “U _ref ” pin of the PWM controller, and the second terminal of the fourth resistor is connected to the third ceramic capacitor and the pin “R _t / C _t ” of the PWM controller, the pin is “OUT” PWM- the controller through the fifth resistor it is connected to the base of the key transistor, the emitter of the key transistor is connected to the seventh resistor and through the sixth resistor it is connected to the pin “Isen” of the PWM controller and to the fourth ceramic capacitor, the collector of the key transistor is connected to the initial terminal of the primary winding of the pulse transformer, a common point between negative terminal of the first electrolytic capacitor, terminal "GND" of the PWM controller, second terminals of the second, seventh resistor and the first, third, fourth ceramic a capacitor connected to the input terminal of negative potential «-U _Rin" power supply, further introduced into the circuit device, the first zener diode, the eighth resistor, a MOS switch, a ninth resistor, a second zener diode, resistor tenth, eleventh resistor, a third zener diode, a second electrolytic capacitor, twelfth resistor, rectifier diode, third electrolytic capacitor, an external feedback signal proportional to the output voltage of the power source is supplied to the cathode of the first zener diode , the anode of the first Zener diode through the eighth resistor is connected to the anode of the MOS relay LED, the cathode of the MOS relay LED is connected to the output terminal of the negative potential of the power supply “-U _o ”, the drain of the first transistor of the MOS relay through the ninth resistor is connected to the common point between the tenth resistor , the cathode of the second zener diode and the output «U _ss" PWM controller connected between a positive terminal of the second electrolytic capacitor, the cathode of the third zener diode and the primary winding of the pulse transformer via odi umpteenth resistor connected to the second terminal of the tenth resistor and to the input terminal of positive potential «+ U _Rin" power supply, parallel to the base-emitter of transistor is connected twelfth resistor, the initial output of the secondary winding of the pulse transformer is connected to the anode of the rectifier diode, the rectifying diode cathode is connected to the positive terminal of the third electrolytic capacitor and to the output terminal of the positive potential device “+ U _pit.su ”, the final terminal of the secondary the pulse transformer windings are connected to the negative terminal of the third electrolytic capacitor and to the output terminal of the negative potential device “-U _pit.su ”, the drain of the second MOS relay transistor, the anode of the second and third zener diodes, the negative terminal of the second electrolytic capacitor are connected to the negative potential input terminal “ -U _in "power supply.

In FIG. 4 shows the electrical circuit of the hot-wire for a power supply with a high-voltage input. The diagram indicates:

The power supply is built on the basis of the well-known prototype [2] and can be included in the circuit of a power supply operating from a wide range of input voltages of at least 300-700 V.

Consider the composition and work of the proposed PP.

Terminal «+ U _Rin", supplied with the input power supply voltage, is connected to the connection point of the input terminals of the tenth and eleventh resistor 23 of the resistor 24. The output of the tenth resistor 23 is connected to a voltage terminal «U _ss" chip PWM controller 10. The output of the eleventh resistor 24 is connected to the cathode of the third zener diode 25, the positive terminal of the second electrolytic capacitor 26 and the final terminal of the primary winding of the pulse transformer. The initial output of the primary winding of the pulse transformer is connected to the collector of the key transistor 16.

The external feedback signal "U _OS " voltage is applied to the cathode of the first zener diode 18, the anode of which is connected to the output of the eighth resistor 19, the other output of which is connected to the anode of the MOS relay 20 LED, the cathode of the MOS relay 20 is connected to the negative polarity terminal of the output power supply voltage "-U _o ". The drain of one transistor of the MOS relay 20 is connected to the terminal of the ninth resistor 21, the second terminal of which is connected to the power terminal "U _ss " of the PWM controller 10. The drain of the second transistor of the MOS relay 20 is connected to the common wire of the device. The common wire is connected to the input terminal of the device, to which the negative potential of the input voltage "-U _in " is supplied. The second output of the ninth resistor 21 is connected to the cathode of the second zener diode 22, the positive terminal of the first electrolytic capacitor 1 and the output of the first resistor 2 of the voltage divider. The other terminal of the first resistor 2 is connected to the terminal of the second resistor 3 of the voltage divider, the terminal of the third resistor 4, the terminal of the second ceramic capacitor 7 and the feedback circuit U _fb »of the PWM controller 10.

The second terminal of the third resistor 4 is connected to the second terminal of the second ceramic capacitor 7 and the COMP terminal - a circuit that sets the gain of the internal amplifier of the error signal of the PWM controller 10 circuit. The output of the reference voltage source "U _ref " of the PWM controller 10 circuit is connected to the terminal the fourth resistor 6 and the output of the first ceramic capacitor 5. The second output of the fourth resistor 6 is connected to the output of the frequency-setting circuit "R _t / C _t " of the PWM controller 10 and the output of the third ceramic cond sensor 8.

The output of the PWM controller microcircuit “OUT” is connected to the output of the fifth resistor 13. The other output of the fifth resistor 13 is connected to the base of the key transistor 16. A twelfth resistor 27 is connected between the base and emitter of the key transistor 16. Isen current feedback The PWM controller 10 is connected to the terminal of the sixth resistor 14 and to the terminal of the fourth ceramic capacitor 12. Another terminal of the sixth resistor 14 is connected to the emitter of the key transistor 16 and the device common wire through the seventh resistor 17.

The negative polarity input terminal “-U _in ” of the device is connected to the anodes of the second and third zener diodes 22, 25, the negative terminal of the first electrolytic capacitor 1, the other terminal of the second resistor 3 voltage divider, the second terminals of the first, third, fourth ceramic capacitors 5, 8, 12 , the emitter of the key transistor 16 and the output of the "GND" PWM controller.

A rectifier diode 28 is included in the secondary winding of the pulse transformer 15, the anode of which is connected to the beginning of the secondary winding, and the cathode is connected to the output terminal of the positive potential device “+ U _pit.su ”. The final output of the secondary winding of the transformer is connected to the output terminal of the negative potential device "-U _pit.su ". Between the output terminals of the device included a filtering third electrolytic capacitor 29.

The device operates as follows.

GZ for the power source is based on a single-cycle flyback voltage converter. The element forming the generation of the pulse sequence at the output of the device is a PWM controller microcircuit 10. The PWM controller microcircuit 10 includes a transistor cascade that amplifies the current output signal. This allows you to connect to the output circuit of the PWM controller 10 chip as the gate circuit of the MOS transistor, and the base circuit of the bipolar transistor.

For the considered circuits (Figs. 3 and 4) transistors of medium power are used. The use in a utility model of a bipolar transistor is due to the requirements of the structural layout of the device and is not a fundamental distinguishing factor from the prototype (Fig. 3), in which a MOS transistor is used. The domestic industry provides the production of a large range of medium power bipolar transistors in various cases and with a wide range of operating temperature. Also, it is not a distinctive factor from the prototype to install the twelfth resistor 27 in the emitter-base circuit of the key transistor 16.

GZ input terminals: “+ U _in ”, “-U _in ” are connected directly to the input voltage circuit of the power source. The “U _os ” terminal is connected to the output circuit of the power supply, and the “-U _o ” terminal is connected to the output terminal of the negative potential of the power supply.

The DC voltage is supplied to the input terminal of the device “+ U _I ” and to the voltage stabilizer, consisting of the tenth resistor 23 and the second zener diode 22. The stabilization voltage of the zener diode is selected based on the required power supply voltage “U _ss ” of the PWM controller 10.

The value of the tenth resistor 23 is selected based on the ratio of the voltage difference (U _in - U _{st. 22} ) to the value of the stabilization current of the second zener diode 22, where U _st . 22 is the stabilization voltage of the zener diode 22.

The tenth resistor 23 limits the amount of charge current of the first electrolytic capacitor 1. The first electrolytic capacitor 1 and the second electrolytic capacitor 26 are energy storage devices.

Energy stored in capacitive storage:

where C is the capacitance of the capacitor;

U is the value of the voltage applied to the capacitor.

The capacitance value of these capacitors is selected taking into account the temperature range of the operation of the gas supply for the power source. When the input voltage is switched, the first electrolytic capacitor 1 is charged to a voltage sufficient to turn on the microcircuit of the PWM controller 10, the internal generator of the microcircuit of the PWM controller 10 is started. On the waveform No. 1 of FIG. 5 is the time t1.

The generator generates a pulse sequence with a frequency, the value of which is determined by the values of the third ceramic capacitor 8 and the fourth resistor 6. The pulse sequence is formed in the output circuit “OUT” of the PWM controller 10 (shown on the oscillogram No. 2 of Fig. 5), and enters the base circuit of the key transistor 16. For the operation of the PWM controller microcircuit 10, the control signals are the voltages applied to the inputs “U _fb ” and “COMP”. The process of generating the output pulses depends on the voltage level at the “U _fb ” pin of the PWM controller 10. This level is set by the values of the first and second resistors 2, 3 of the voltage divider. The values of the third resistor 4 and the second ceramic capacitor 7 determine the gain of the mismatch signal of the internal operational amplifier, which is part of the PWM controller 10.

The first ceramic capacitor 5 functions as a filter capacitor for the reference circuit "U _ref ".

An output voltage divider of the microcircuit of the PWM controller 10 is assembled on the fifth resistor 13 and the twelfth resistor 27, which sets the base current of the key transistor 16.

The elements are the eleventh resistor 24, the third zener diode 25, the second electrolytic capacitor 26 form a voltage stabilizer and an energy storage device, which is transmitted through the pulse transformer 15 to the output terminals of the _{mains supply} “+ U _{power supply} ”, “-U _{power supply} ” for starting the _control system source nutrition (Fig. 2).

The energy storage device is supplied directly from the input circuit of the power source, that is, from the terminals “+ U _in ”, “-U _in ”.

The magnitude of the input voltage on the primary winding of the pulse transformer 15 is limited by the stabilization voltage of the third zener diode 25.

The magnitude of the pulse current through the primary winding of the pulse transformer 15 is limited to the eleventh resistor 24. The second electrolytic capacitor 26 connected to the output of the primary winding of the pulse transformer performs the function of energy storage. The amount of energy stored in the primary winding of the pulse transformer 15 is directly proportional to the current:

The inductance L of the primary winding of a pulse transformer is determined from the relation:

The amount of energy E stored in the inductance of the primary winding of the pulse transformer 15 must be sufficient to provide the required pulse power in the load circuit, that is, for the power supply circuit of the SU with a voltage converter, a variant of which is shown in FIG. 2.

The pulse mode of operation of the key transistor 16 is shown in the waveform No. 3 of FIG. 5 (the form of the pulse voltage in the collector-emitter transistor circuit).

At the moment of the closed state of the key transistor 16, the accumulated energy is transferred to the secondary circuit of the transformer and to the load - the power supply circuit SU (terminals “+ U _{power supply} ”, “-U _{power supply} ”) with a voltage converter (Fig. 2).

On the waveform No. 4 of FIG. 5 shows the shape of the pulse on the secondary side of the pulse transformer 15, in the anode circuit of the rectifier diode 28.

On the waveform No. 5 of FIG. 5 shows the shape of the pulse voltage at the output of the GB.

The oscillograms shown in FIG. 5, explain the operation algorithm of the HR for the power source.

At the moment of switching on, that is, when the input voltage is applied to the terminals “+ U _in ” and “-U _in ”, the voltage on the first electrolytic capacitor 1 (section “a” on the waveform No. 1 of Fig. 5) and on the second electrolytic capacitor begin to increase 26. At time t1, the voltage at the first electrolytic capacitor 1 and at the output of “U _ss ” becomes equal to the turn-on voltage of the microcircuit of the PWM controller 10. After the microcircuit is turned on, the PWM controller 10 generates an output pulse at its output (output “OUT”), with amplitude equal to voltage 2U, s Resp voltage switching circuit PWM controller 10. Next, in the time interval t1-t2 is generated an output pulse of the PWM controller chip 10 shown on the waveform №2. Under the action of the load current in the power circuit "U _ss " of the PWM controller 10 chip, a voltage drop occurs - in the time interval t1-t2, the voltage at the first electrolytic capacitor 1 decreases (interval "b" on the waveform No. 1), as a result, the pulse amplitude at the output “OUT” of the microcircuit PWM controller 10 drops as it is shown on the oscillogram No. 2.

The decrease in voltage at the output “U _ss ” of the power supply of the PWM controller 10 microcircuit is explained by the fact that after the internal generator is started, the PWM controller 10 microcircuit starts to work, forming an output pulse at the “OUT” pin, which opens the key transistor 16. In this case, the power consumption by the power supply circuit “U _ss ” of the PWM controller 10 chip increases and the amount of energy stored in the first electrolytic capacitor 1 starts to decrease, which is exactly what is seen in the decrease in voltage on the first electrolytic capacitor 1 and shown on the waveform No. 2 - section "b" in the circuit "OUT".

U, определяется гистерезисом по напряжению питания и является параметром конкретного типа микросхемы ШИМ-контроллера 10.The voltage reduction in this interval (t1-t2) occurs from the level U2 (corresponding to the turn-on voltage of the PWM controller 10 chip) to the voltage U1 (corresponding to the turn-off voltage of the PWM controller 10 chip). The difference (U2-U1) indicated by

U, is determined by the hysteresis of the supply voltage and is a parameter of a specific type of chip PWM controller 10.

In this time period (t1-t2), the key transistor 16 is open, and current flows through the primary winding of the pulse transformer 15. The inductance of the primary winding of the pulse transformer 15 accumulates energy:

where L is the inductance of the primary winding of a pulse transformer. As shown in FIG. 4, the pulse transformer 15 and the rectifier diode 28 are connected according to the flyback converter, during the open state of the key transistor 16, the rectifier diode 28 does not conduct output current.

At time t2, the voltage at the first electrolytic capacitor 1 decreases to the lower level of the supply voltage U1 of the PWM controller 10. At this point, the PWM controller 10 is turned off and the output pulse disappears at its output “OUT”. The key transistor 16 is closed, and the polarity of the voltage on the windings of the pulse transformer 15 according to the law of EMF self-induction changes sign.

As can be seen from the waveform No. 3, U _ke is the collector-emitter voltage of the key transistor 16. At the time of closing of the key transistor 16, a voltage surge occurs on the collector. The amplitude of the ejection depends on the input voltage level at the second electrolytic capacitor 26 and the magnitude of the magnetization inductance Lm of the primary winding of the pulse transformer 15. Then, after a while, the peak of the ejection drops to a steady value equal to the voltage on the second electrolytic capacitor 26. The voltage drop to this level is accompanied by an oscillatory the process, the view of which is shown in section “c” of waveform No. 3.

The voltage fluctuation in the collector-emitter circuit of the key transistor 16 is due to a transient process occurring in the resonant circuit formed by "parasitic circuits" of the primary winding of the pulse transformer 15, namely, the leakage inductance Ls and the inter-turn capacitance C of the primary winding of the pulse transformer 15. These are "stray" parameters depend on the design and manufacturing quality of the pulse transformer 15.

At time t2, the polarity of the voltage across the windings of the pulse transformer 15 changes its sign. The rectifier diode 28 opens and starts to conduct current, charging the third electrolytic capacitor 29 and transferring the energy of the pulse transformer 15 to the circuit “U _pit.su ” - supplying the SU with a power source (Fig. 2).

On the time interval t2-t3, the current consumption by the power circuit “U _ss ” of the PWM controller 10 microcircuit is practically zero, while the first electrolytic capacitor 1 is charging and the voltage at the “U _ss ” terminal starts to increase. The process of charging the first electrolytic capacitor 1 proceeds until the voltage in the circuit "U _ss " reaches the turn-on voltage of the microcircuit of the PWM controller 10, and then the GZ starts and the pulse sequence is again formed at the OUT output, which drive the 16-volt key transistor work in key mode. A pulsed current will flow through the primary winding of the pulse transformer 15. In the transformer, the magnetic circuit of which is made with a gap, energy is stored, which, when the key transistor is closed, enters the secondary circuit of the transformer and through the rectifier diode enters the output circuit of the GZ “U _pit.su ”.

The shape of the pulse voltage at the output of the HZ is shown on the waveform No. 5 (Fig. 5).

A prerequisite for the performance of the GZ is the condition for the equality of the volt-second areas S1 and S2 (shaded areas) on the waveform No. 4 (Fig. 5) in the secondary circuit of the pulse transformer 15. Otherwise, the magnetic circuit of the pulse transformer 15 will saturate.

The processes occurring in the time interval 0-t2 are repeated in the HR until the moment of switching on and reaching the nominal operating mode of the SU with the power source shown in FIG. 2. After starting and completing the transition process of turning on the power supply, the control system of the power supply is powered from the additional winding of the power transformer (T1.3 in Fig. 2) of the power supply and the power supply circuit of the control system from the power supply is no longer needed.

At the same time, at the output of the power source (which includes the power supply), the nominal output voltage is set. At the input PP is formed U _oc signal whose value is proportional to the nominal value of the output voltage U _O power supply. This opens the first Zener diode 18. The stabilization current of the first Zener diode 18 and the LED current of the MOS relay 20 are set by the value of the eighth resistor 19. In the output circuit of the MOS relay 20, the current is limited to the value of the ninth resistor 21. When the MOS relay 20 is activated, the circuit “U _ss »Power supply of the PWM controller microcircuit 10.

The chip of the PWM controller 10 is turned off, the operation of the HR stops.

Thus, when the power source (Fig. 2) reaches the rated state of operation, the power supply is turned off. Such an algorithm of operation of the GB provides a decrease in the level of spurious noise in the output circuit of the power source.

In the event of an unauthorized shutdown of the input voltage of the power source and subsequent switching it on again, that is, when switching (with a characteristic "bounce") of the input voltage at the "U _I " terminals of the source, the power supply will not start the power source instantly, but only after the necessary amount of energy has been accumulated in the first and second electrolytic capacitors 1, 26. When operating from a high-voltage input voltage of 300-700 V, such an operation algorithm provides a “soft” transient switching process and increases the reliability of the power source and I.

In accordance with the utility model described above, a start-up generator for a power supply with a high-voltage input of this design is developed and manufactured at the enterprise, which is widely used in many products.

Thus, due to the fact that in the known device containing the PWM controller chip, the first electrolytic capacitor, the first resistor, the second resistor, the third resistor, the first ceramic capacitor, the fourth resistor, the second ceramic capacitor, the third ceramic capacitor, the fourth ceramic capacitor, fifth resistor, sixth resistor, pulse transformer, key transistor, seventh resistor, additionally introduced the first zener diode, eighth resistor, MOS relay, ninth resistor, second stub ititron, tenth resistor, eleventh resistor, third zener diode, second electrolytic capacitor, twelfth resistor, rectifier diode and third electrolytic capacitor with the above connections, improved electrical and operational characteristics.

Information sources

1. Reference "Microcircuits for switching power supplies and their application." 2nd edition - M .: DODEKA, 2000. - p. 216, 300.

2. Integrated circuits 1114ЕУ7У, 1114ЕУ8У, 1114ЕУ9У, 1114ЕУ10У. Technical conditions AEYAR.431000.379-01TU. 2005 - a prototype.

Claims (1)

A start generator for a high voltage input power supply comprising a PWM controller chip, a first electrolytic capacitor, a first resistor, a second resistor, a third resistor, a first ceramic capacitor, a fourth resistor, a second ceramic capacitor, a third ceramic capacitor, a fourth ceramic capacitor, and a fifth resistor, sixth resistor, pulse transformer, key transistor, seventh resistor, the positive terminal of the first electrolytic capacitor is connected to the terminal "U _{c c} ”PWM controller, the common point between the first, second, third resistor and the second ceramic capacitor is connected to the“ U _fb ”pin of the PWM controller, the second terminals of the third resistor and the second ceramic capacitor are connected to the“ COMR ”pin of the PWM controller, common point between the first ceramic capacitor and the fourth resistor is connected to the output of the "U _ref " PWM controller, and the second output of the fourth resistor is connected to the third ceramic capacitor and the output of "R _t / C _t " PWM controller, the output is "OUT" PWM controller through the fifth resistor is connected to the base of the key transistor, the emitter of the key transistor is connected to the seventh resistor and connected through the sixth resistor to the pin “Isen” of the PWM controller and to the fourth ceramic capacitor, the collector of the key transistor is connected to the initial terminal of the primary winding of the pulse transformer, a common point between the negative the output of the first electrolytic capacitor, the output of the "GND" PWM controller, the second terminals of the second, seventh resistor and the first, third, fourth ceramic cond The sensor is connected to the negative potential input terminal “-U _in ” of the power source, characterized in that the first zener diode, the eighth resistor, the MOS relay, the ninth resistor, the second zener diode, the tenth resistor, the eleventh resistor, the third zener diode, the second electrolytic are introduced into the device circuit capacitor, twelfth resistor, rectifier diode, third electrolytic capacitor, an external feedback signal proportional to the output voltage of the power source is supplied to the cathode of the first zener diode I, the anode of the first zener diode through the eighth resistor is connected to the anode of the LED MOS switch, the cathode of the LED MOS relay connected to the output terminal of the negative power source potential «-U _O", the drain of the first MOS transistor switch through the ninth resistor is connected to the common point between the tenth a resistor, a cathode of the second zener diode and the output of "U _cc " PWM controller, interconnected the positive terminal of the second electrolytic capacitor, the cathode of the third zener diode and the primary winding of the pulse transformer through one the eleventh resistor is connected to the second terminal of the tenth resistor and to the input terminal of the positive potential “+ U _in ” of the power supply, a twelfth resistor is connected in parallel with the emitter of the key transistor, the initial output of the secondary winding of the pulse transformer is connected to the anode of the rectifier diode, while the cathode of the rectifier diode is connected to the positive terminal of the electrolytic capacitor and the third output terminal to the positive potential of the device «+ U _pit.su 'end terminal of the secondary second winding of the pulse transformer is connected to the negative terminal of the electrolytic capacitor and the third output terminal with the negative potential of the device «-U _pit.su" drain of the second MOS transistor switch, the anode of the second and third Zener diodes, the negative terminal of the second electrolytic capacitor connected to the input terminal of negative potential "-U _in " power supply.

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