KR101034897B1 - Apparatus for driving switching device of resonant switching mode power supply - Google Patents

Abstract

PURPOSE: An apparatus for driving a switching device of a resonant switching mode power supply is provided to control dead time according to the size of a load, thereby preventing harmonic noise. CONSTITUTION: A load sensing unit(110) senses the size of a load. A frequency controller(120) outputs a square wave signal whose frequency is controlled by controlling the charging/discharging time of a condenser according to a change of a feedback current value inputted from the load sensing unit. A dead time controller(130) outputs two square wave signals whose dead time is adjusted by delaying ascending time or descending time of a square wave signal according to a change of a feedback current value.

Description

Apparatus for driving switching device of resonant switching mode power supply}

The present invention relates to a driving device of a switching element for controlling the dead time of an output square wave of a power MOSFET used in a resonant switching mode power supply.

Recently, resonant switching mode power supplies have been used in power supplies for LCD and PDP TVs. The resonant switching mode power supply is composed of two power MOSFETs, a resonant tank and a transformer. In such a resonance type switching mode power supply, when a driving signal is applied to the upper and lower power MOSFETs, a shoot-through phenomenon may occur in which the upper and lower power MOSFETs are simultaneously conducted.

Conventionally, in order to prevent the shoot-through phenomenon between the upper and lower power MOSFETs, as shown in FIG. 1, the rising and falling times of the output square waves HO and LO of the upper and lower power MOSFETs are controlled so as not to overlap each other. . In other words, the output square waves HO and LO are controlled so that the output square waves HO and LO have a dead time in which both the output square waves HO and LO have a "LOW" value.

On the other hand, in order to improve the efficiency of the resonant switching mode power supply, a conventional PFM (pulse frequency modulation) method of adjusting the frequency of the output square wave (HO, LO) according to the size of the load connected to the secondary side of the transformer is used. . However, since the control apparatus of the conventional resonant switching mode power supply does not consider the dead time in applying the PFM method, the square wave in which the dead time is fixed even if the frequency of the output square wave (HO, LO) is adjusted, that is, the fixed dead Two square waves with time are output from the upper and lower power MOSFETs.

The control method having a fixed dead time has a problem in that no load power consumption, that is, standby power, is generated because power consumption generated by the switching element in the light load or the standby mode occupies a large proportion to reduce efficiency. In addition, when the resonant frequency of the power supply is increased, there is a problem in that harmonic noise is generated because the proportion of the fixed dead time in the output square wave becomes relatively large.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and provides a switching device driving apparatus of a resonant switching mode power supply which can reduce efficiency decrease in light load or standby mode and can prevent generation of harmonic noise. have.

The problem to be solved by the present invention is not limited to the above-mentioned problem, another problem to be solved by the present invention not mentioned here is those skilled in the art from the following description. Will be clearly understood.

The switching element driving device of the resonant switching mode power supply that controls the output square wave of each power MOSFET so as to have a dead time to prevent the shoot-through between two power MOSFETs according to the present invention, the feedback current value according to the size of the load Load detection unit for detecting the size of the load; A frequency controller for outputting a square wave signal whose frequency is controlled by adjusting the charge / discharge time of the capacitor according to a change in the current value of the feedback current input from the load sensing unit; And a square wave signal input from the frequency control unit to each of the two delay circuits, and delays the rise time or the fall time of the square wave signal according to the change of the feedback current value, so that the dead time is adjusted. And a dead time controller outputting the switching signal.

The frequency control unit of the present invention compares the capacitor with a voltage value of the capacitor by setting a maximum charge voltage value and a minimum discharge voltage value of the capacitor, a current mirror circuit for charging and discharging the capacitor by varying the charge and discharge time according to the feedback current value. And a RS latch for controlling the charging and discharging start timing of the current mirror circuit according to the output signal of the comparator and outputting a square wave signal according to the charging and discharging start timing.

The frequency control unit of the present invention is characterized by reducing the frequency of the square wave signal when the load increases, and increasing the frequency of the square wave signal when the load decreases.

The dead time controller of the present invention includes a current bias circuit for generating a reference current of a delay circuit by detecting an amount of change in a feedback current value, and a delay circuit, and generates a adjusted dead time by inputting a reference current and the square wave signal. And a dead time generating circuit.

The delay circuit of the present invention is characterized by including a capacitor and a current mirror circuit for delaying the rise time or fall time of the square wave signal by varying the charge and discharge time of the capacitor according to the reference current.

The dead time controller of the present invention is characterized by increasing the dead time of the square wave signal when the load increases, and reducing the dead time of the square wave signal when the load decreases.

By the above problem solving means, the resonant switching mode power supply of the present invention can control the dead time in accordance with the size of the load, thereby improving the conversion efficiency, it is possible to prevent harmonic noise.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

2 is a view for explaining a resonance type switching mode power supply having a switching device driving apparatus according to an embodiment of the present invention.

As shown in FIG. 2, the switching device driving apparatus 100 of the resonance type switching mode power supply according to the embodiment of the present invention includes a load detector 110, a frequency controller 120, and a dead time controller 130. It includes.

The power MOSFETs SW1 and SW2 of the resonant switching mode power supply are driven by a bootstrap method composed of a diode D _boot and a capacitor C _boot . In addition, the resonant tank of the resonant switching mode power supply is composed of a transformer primary side inductor L _p , a resonant inductor L _r , and a resonant capacitor C _r . The DC characteristics of the resonant switching mode power supply are determined by the resonance parameters. Two resonance frequencies f ₁ and f ₀ exist, and each is represented by the following Equations 1 and 2 below.

When the input voltage is 400V, the resonant switching mode power supply operates normally, and the switching frequency has the maximum gain near the resonance frequency f ₁ . The higher the switching frequency, the smaller the gain. According to this principle, the operating frequency of the drive signal of the switching element is maximized when in the standby mode or at light load.

As described above, the switching device driving apparatus 100 based on the pulse frequency modulation (PFM) control method of adjusting the frequency according to the size of the load R0 includes two dead times suitable for the size of the load R0. Output a square wave signal. The square wave signal is input to the upper and lower level shifters 141 and 142, and the respective level shifters 141 and 142 output signals for driving two power MOSFETs SW1 and SW2.

The load detector 110 is connected to a resonant switching mode power supply circuit and forms a feedback loop composed of a photocoupler and a shunt regulator. The load detector 110 detects the magnitude of the load R0 by varying the value of the feedback current I _Load according to the magnitude of the load R0.

The frequency controller 120 inputs a sum of I _Load and I _RFmin current and outputs a duty ratio square wave signal of 50% or less. The operating frequency of the output square wave signal increases linearly with the magnitude of the input current. The input current I _RFmin is a constant current source, and the feedback current I _Load flowing through the photocoupler is inversely proportional to the load (R0) of the resonant switching mode power supply.

The dead time controller 130 receives a square wave signal output from the frequency controller 120 as an input. In addition, I _ref2 current (= I _RFmin / 5) and I _d current (= -I, which were converted by the internal current bias circuit (indication number 131 in FIG. 3) with the sum of the I _Load current and I _RFmin current as inputs. The difference of _Load / 10) is used as the reference current. The outputs of the dead time controller 130 are two square wave signals in which dead time exists in which the output logic values are all “low”. Dead time is linearly related to the magnitude of the reference current. I _ref2 of the reference current of the dead time controller 130 is a constant current source regardless of temperature and supply voltage, and I _d of the reference current is a current source inversely proportional to the magnitude of the load R0.

Since the magnitude of the feedback current I _Load is inversely proportional to the magnitude of the load R0, the input current increases as the magnitude of the load R0 decreases. Accordingly, the operating frequencies of the two square wave signals output from the dead time controller 130 are increased, and the dead time is narrowed. Therefore, the dead time is appropriately adjusted according to the size of the load R0, so that unnecessary power consumption of the upper and lower power MOSFETs SW1 and SW2 can be reduced. As a result, the power conversion efficiency of the resonant switching mode power supply can be improved.

3 is a view for explaining a switching device driving apparatus of the resonance type switching mode power supply according to an embodiment of the present invention.

As shown in FIG. 3, the frequency controller 120 outputs a square wave signal whose frequency is controlled by adjusting the charge / discharge time of the capacitor CF according to the change of the feedback current value input from the load detector 110. .

The frequency controller 120 sets the capacitor CF, a current mirror circuit for charging and discharging the capacitor by varying the charge / discharge time according to the feedback current value, and the maximum charge voltage value and the minimum discharge voltage value of the capacitor CF. A comparator for comparing with the voltage value of the capacitor, and an RS latch for controlling the charge and discharge start timing of the current mirror circuit in accordance with the output signal of the comparator, and outputs a square wave signal according to the charge and discharge start timing.

The capacitor CF of the frequency controller 120 and the value of the resistor R _ex1 of the load detector 110 determine the minimum value of the operating frequency. The reference current I _ref1 used in the frequency controller 120 is expressed by the following equation (3) by the reference voltage V _ref1 , the resistor R _ex1, and the feedback current I _Load .

The magnitude of the current I ₁ and the current I ₂ is equal to the current I _ref1, and the current I ₃ flowing through the MN4 and MN5 is twice the current I _ref1 . When the voltage value of the capacitor CF charged by the current I ₂ becomes larger than the maximum charging voltage value V _ref3 of the capacitor, the non-inverting output Q of the RS latch becomes “low” and MN6 is turned off. The capacitor CF is discharged through MN4 and MN5.

When the voltage of the capacitor CF becomes smaller than the minimum discharge voltage value V _ref2 , the non-inverting output Q of the RS latch becomes “high” and MN6 turns on. The value of the current I ₃ is 0 A, and the capacitor CF is charged by the current I ₂ . In this manner, the frequency controller 120 oscillates, and the non-inverting output Q of the RS latch outputs a square wave signal having a 50% duty ratio.

When the size of the load R0 of the resonant switching mode power supply is maximum, the value of the feedback current I _Load of the porter coupler is 0A. The currents I _ref1 , I ₁ and I ₂ are equal to the current I _RFmin, and the discharge current I ₃ of the capacitor CF is twice the I _RFmin . Therefore, the charge / discharge time of the capacitor CF is determined by the current I _RFmin and has a maximum charge / discharge cycle. That is, when the load R0 of the resonant switching mode power supply is maximum, the operating frequency is minimum, which is expressed by Equation 4 below.

When the size of the load R0 of the resonant switching mode power supply becomes small, the size of the feedback current I _Load becomes large. As a result, the charge / discharge current of the capacitor CF is increased to increase the operating frequency.

As described above, the frequency controller 120 decreases and outputs the frequency of the square wave signal when the load R0 increases, and increases and outputs the frequency of the square wave signal when the load R0 decreases. This can be seen from the circuit diagram of FIG. 3 and the relationship between the operating frequency and the current according to the magnitude of the feedback current I _Load through the equation (4).

The dead time controller 130 outputs two square wave signals having an optimal dead time according to the size of the load R0 by using the feedback current I _Load of the porter coupler for detecting the load R0. That is, the dead time controller 130 inputs the square wave signal input from the frequency controller 120 to each of the two delay circuits (see FIGS. 4 and 5), and the square wave signal rises according to the change of the feedback current I _Load value. By delaying the time or fall time, two square wave signals with a dead time adjusted are output as switching signals of each of the power MOSFETs SW1 and SW2.

To this end, the dead time controller 130 includes a current bias circuit 131 for detecting a change amount of the feedback current I _Load value and generating a reference current of the delay circuit, and a delay circuit, and the reference current and frequency controller 120. And a dead time generation circuit 132 for generating the adjusted dead time by inputting a square wave signal of.

As the load R0 decreases, the feedback current I _Load increases, and the current I _ref1 and the currents I ₁ , I ₂ , I _4, and I ₅ increase. The process of generating the reference current I ₈ by the current bias circuit 131 is represented by the current relationship shown in Equations 5 to 8 below.

A current I ₈ having a current relationship as shown in Equation 8 becomes a reference current of the delay circuit of the dead time generating circuit 132. The reference current I ₈ is a function consisting of the currents I _RFmin and I _Load , as shown in equation (8). _Since the magnitude of the current I _RFmin is a fixed value fixed by the voltage V _ref1 and the resistor R _ex1 , the reference current I ₈ of the dead time generating circuit 132 becomes a function of the feedback current I _Load , and the feedback current I _Load Since the magnitude of V is inversely proportional to the magnitude of the load R0, the reference current I ₈ is inversely proportional to the magnitude of the resonant switching mode power supply load R0.

4 is a view for explaining a dead time generation circuit according to an embodiment of the present invention.

As shown in FIG. 4, the dead time generating circuit 132 inputs one square wave signal from the frequency control unit 120 to the PFM input terminal, and inputs two complementary square wave signals having dead time to the HVG and LVG output terminals. Output In addition, the dead time generation circuit 132 inputs the reference current I ₈ from the current bias circuit 131 through the B1 and B2 input terminals.

The dead time generating circuit 132 includes two NAND gates 133 which input square wave signals PFM and output signals of the delay circuit 134, and output signals and reference currents of the NAND gate 133. Two delay circuits 134 having I ₈ as an input and a plurality of inverters 135 for inverting and outputting the input signal as necessary. Since the dead time is determined by the propagation delay time of the delay circuit 134, the same delay circuit 134 is used in FIG. 4 so that the top output square wave signal and the bottom output square wave signal have the same delay time.

5 is a diagram for describing a delay circuit according to an exemplary embodiment of the present invention.

The delay circuit 134 of FIG. 5 corresponds to one delay circuit 134 of FIG. 4, and an operating current of the delay circuit is a reference current I ₈ . Specifically, the delay circuit 134 inputs a square wave signal to the PFM input terminal, inputs a reference current I ₈ to the B1 and B2 input terminals, and outputs one square wave signal having a dead time to the output terminal. The output stage is either the HVG output stage or the LVG output stage of FIG. 4.

The delay circuit 134 includes a capacitor C ₁ and a current mirror circuit which delays the rise time or fall time of the square wave signal by varying the charge and discharge time of the capacitor C1 according to the reference current I ₈ . That is, the delay circuit 134 uses the charge / discharge time of the capacitor C ₁ .

When the input of the square wave signal of the delay circuit 134 is "high", the capacitor C ₁ is discharged by the current I ₁₁ flowing in MN1, and the output of the delay circuit 134 is "high". At this time, the voltage of the capacitor C ₁ is delayed by the time for discharging to 1/2 of the circuit supply power supply VDD of about 5V. When the square wave signal input of the delay circuit 134 is "low", the capacitor C ₁ is charged by the current I ₁₀ , and the output of the delay circuit 134 is "low". At this time, the voltage of the capacitor C ₁ is delayed by the time for charging to 1/2 of VDD.

Since the delay circuit 134 consists of a current mirror circuit, the magnitudes of the currents I ₉ and I ₁₀ are equal to the reference current I ₈ . Since the magnitude of the feedback current I _Load is inversely proportional to the magnitude of the load R0, the charge / discharge time of the capacitor C ₁ is inversely proportional to the magnitude of the load R0. That is, when the size of the load (R0) is large, the charge and discharge time of the capacitor (C ₁₎ is a slow down, if the size of the load (R0) is small, charging and discharging time of the capacitor (C ₁₎ is faster.

As described above, the dead time controller 130 increases the dead time of the output square wave signal when the load R0 increases, and decreases the dead time of the output square wave signal when the load R0 decreases. The dead time controller 130 includes a current bias circuit 131 and a dead time generation circuit 132 to optimize the dead time according to the size of the load R0.

6 is a waveform diagram illustrating an output square wave signal according to an embodiment of the present invention. Specifically, FIG. 6A illustrates a square wave signal output from the switching element driving apparatus when the load is large, and FIG. 6B illustrates output from the switching element driving apparatus when the load is small or no load. It shows a square wave signal.

As shown in FIG. 6, the square wave signal output from the switching element driving device of the resonant switching mode power supply according to the embodiment of the present invention reduces the frequency of the output square wave signal while the load is large, and output square wave. Increase the dead time of the signal. In addition, when the load is small, the frequency of the output square wave signal is increased while reducing the dead time of the output square wave signal.

As such, by adjusting the frequency of the square wave signal output from the switching element driving device, that is, the switching signal of the power MOSFET according to the size of the load, and controlling the dead time, the efficiency can be improved and the harmonic noise can be prevented. There is an effect.

FIG. 7 is a diagram illustrating a design of a resonance type switching mode power supply having a switching device driving apparatus according to an embodiment of the present invention on a simulation program.

As shown in FIG. 7, after the resonant switching mode power supply is designed on the simulation program, each parameter value is input as follows. DC characteristics make output voltage 20V and output current 11A. The resonance parameter sets a transformer turn ratio of 0.05, a resonance inductor L _r of 70 uH, a resonance capacitor C _r of 39 Hz, and a resonance frequency f ₁ of 96 Hz. The power MOSFET has a maximum drain source voltage of 500V, a threshold voltage of 4V, and an on resistance of 0.85Ω. In the switching characteristics, the turn-on delay time is 35 ms, the input capacitance is 1,600 ms, and the output capacitance is 350 ms.

When the simulation program is executed after the parameter value is input, the result of the correlation between the feedback current and the dead time as shown in FIG. 8 and the power conversion efficiency result as shown in FIG. 9 can be derived.

8 is a graph illustrating a correlation between a feedback current and a dead time according to an embodiment of the present invention.

8 is a graph showing a result of simulating the correlation of the dead time according to the feedback current, and the feedback current I _Load which varies its value according to the load shows an inverse relationship with the dead time. That is, when the load increases and the feedback current I _Load decreases, the dead time increases, and when the load decreases and the feedback current I _Load increases, the dead time decreases.

9 is a graph showing the power conversion efficiency of the resonant switching mode power supply according to an embodiment of the present invention.

FIG. 9 illustrates simulation results of power conversion efficiency of a resonant switching mode power supply having a switching device driving apparatus according to an embodiment of the present invention, and a resonant switching mode power supply having a conventional fixed dead time. As a result, it can be seen that the efficiency of the resonant switching mode power supply with the switching device driving apparatus according to the embodiment of the present invention is increased by 3 to 7% compared with the related art.

As such, the technical configuration of the present invention described above can be understood by those skilled in the art that the present invention can be implemented in other specific forms without changing the technical spirit or essential features of the present invention.

Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the following claims rather than the detailed description, and the meaning and scope of the claims and their All changes or modifications derived from an equivalent concept should be construed as being included in the scope of the present invention.

1 is a waveform diagram showing a conventional square wave signal.

2 is a view for explaining a resonance type switching mode power supply having a switching device driving apparatus according to an embodiment of the present invention.

3 is a view for explaining a switching device driving apparatus of the resonance type switching mode power supply according to an embodiment of the present invention.

4 is a view for explaining a dead time generation circuit according to an embodiment of the present invention.

5 is a diagram for describing a delay circuit according to an exemplary embodiment of the present invention.

6 is a waveform diagram illustrating an output square wave signal according to an embodiment of the present invention.

FIG. 7 is a diagram illustrating a design of a resonance type switching mode power supply having a switching device driving apparatus according to an embodiment of the present invention on a simulation program.

8 is a graph illustrating a correlation between a feedback current and a dead time according to an embodiment of the present invention.

9 is a graph showing the power conversion efficiency of the resonant switching mode power supply according to an embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

100: switching element drive device

110: load detection unit

120: frequency control unit

130: dead time control unit

131: current bias circuit

132 dead time generating circuit

133: Nand Gate

134: delay circuit

135: inverter

CF, C ₁ : condenser

R0: Load

SW1, SW2: Power MOSFET

Claims (6)

A switching element driving device of a resonant switching mode power supply for controlling an output square wave of each of the power MOSFETs so as to have a dead time preventing a shoot-through between two power MOSFETs. A load detector configured to detect a magnitude of the load by varying a feedback current value according to a load size; A frequency controller for outputting a square wave signal whose frequency is controlled by adjusting the charge / discharge time of the capacitor according to a change in the current value of the feedback current input from the load detector; And The square wave signal input from the frequency control unit is input to each of the two delay circuits, and the square wave signal of which the dead time is adjusted is delayed by the rise time or the fall time of the square wave signal according to the change of the feedback current value. A dead time controller outputting a switching signal of each MOSFET; Switching device driving device of the resonant switching mode power supply comprising a. The method of claim 1, The frequency controller may be configured to set a maximum charge voltage value and a minimum discharge voltage value of the capacitor, a current mirror circuit which charges and discharges the capacitor by varying the charge / discharge time according to the feedback current value. A comparator for comparing the voltage value of the capacitor, and an RS latch for controlling the charging / discharging start timing of the current mirror circuit according to the output signal of the comparator, and outputting the square wave signal according to the charging / discharging start timing. A switching element drive device for a resonant switching mode power supply. The method according to claim 1 or 2, The frequency controller decreases the frequency of the square wave signal when the load increases, and increases the frequency of the square wave signal when the load decreases. . The method of claim 1, The dead time controller includes a current bias circuit for generating a reference current of the delay circuit by detecting a change amount of the feedback current value, and the delay circuit, and the adjusted dead by inputting the reference current and the square wave signal. A switching element drive device for a resonant switching mode power supply, comprising: a dead time generation circuit for generating time. The method of claim 4, wherein The delay circuit includes a capacitor and a current mirror circuit for delaying the rise time or fall time of the square wave signal by varying the charge and discharge time of the capacitor according to the reference current. Switching element driving device. The method according to claim 1 or 4, The dead time controller increases the dead time of the square wave signal when the load increases, and reduces the dead time of the square wave signal when the load decreases. Element driving device.

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