KR100765921B1 - DC/DC Converter - Google Patents

Abstract

The present invention relates to a DC / DC converter.

The DC / DC converter according to the present invention includes an inductor unit for charging energy according to an input voltage, a charge switch unit for controlling the charging of the energy in the inductor unit, and the inductor unit for energy charged in the inductor unit. An output unit for outputting to output terminals electrically connected to each of the output switches through switching of output switches connected in parallel to the output switches, feedback voltages obtained by dividing the voltages output to the output terminals through a resistor, and a predetermined reference voltage A comparison unit outputting comparison signals according to a difference between the feedback voltages and the reference voltages, a current sensing unit sensing an amount of current flowing through the inductor unit, and an output from the comparison signals and the current sensing unit. The charging switch is controlled in accordance with a signal to be output, and the output switch according to the comparison signals. And a control unit for controlling the teeth.

According to the present invention, it is possible to operate the DC / DC converter in DCM (Discontinuous Mode) and CCM (Critical Continues Mode) with a simple control structure.

DC / DC Converters, Step-Up, Boost Converters, CCM, DCM

Description

DC / DC Converter {DC / DC Converter}

1 is a view showing a conventional DC / DC converter.

Fig. 2 is a diagram showing the operation timing of Fig. 1;

3 is a view showing the conceptual configuration of a non-isolated multi-output boost converter for explaining a DC / DC converter according to a first embodiment of the present invention.

FIG. 4 is a diagram showing operation timings (when three outputs are generated) for the driving circuit of FIG.

5 is a diagram illustrating DCM and CCM which are operating methods of a boost converter.

6 is a diagram showing the conceptual configuration of a boost converter for generating a positive (+) power source and a negative (-) power source, which are DC / DC converters according to a second embodiment of the present invention;

FIG. 7 is a view showing an operation timing when one positive power and two negative powers are generated during the driving operation of FIG. 6; FIG.

The present invention relates to a DC / DC converter.
FIG. 1 is a diagram illustrating a conventional DC / DC converter, and FIG. 2 is a diagram illustrating an operation timing when N = 3 in FIG. 1.
Referring to Figures 1 and 2 will be described the operation of the conventional DC / DC converter as follows.

1) Turn on switch M1 to build up energy in inductor L.

2) Turn off the switch M1 and turn on the switch S1 to generate all the energy build-up in the inductor L to the output as Vo (1).

3) Turn off switch S1 and turn on switch M1 in the same way as in 1) above to build up energy in inductor L for Vo (2).

4) Turn off the switch M1 and turn on the switch S2 to generate all the energy build-up in the inductor L to the output as Vo (2).

5) Turn off switch S2 and turn on switch M1 in the same way as 1) above to accumulate energy in inductor L for Vo (3).

6) Turn off switch M1 and turn on switch S3 to generate all of the energy build-up in inductor L to the output as Vo (3).

7) Turn off switch S3.

8) Processes 1) to 7) above correspond to one cycle of generating an output voltage at Vo (1), Vo (2), and Vo (3). 1) to 7) are repeated to generate voltages on the outputs Vo (1), Vo (2), and Vo (3). It is determined whether each output voltage is the desired level. The pulse width is adjusted by applying the pulse width of the switch M1 to the corresponding section in the direction of minimizing the error.

Looking at the operation method as described above, when operating the switching frequency of the switch M1 at 1MHz it can be seen that the operating frequency of S1, S2, S3 is 333KHz operating at 1/3 of the switching frequency of M1 to generate the output. In this case, the effective frequency of each output voltage is low, so the ripple voltage of the output becomes large. In general, as the number of outputs increases to N, the effective operating frequency of the output also decreases to 1 / N, which further increases output ripple. In the case of the time bases T5 and T7 of FIG. 2, when the energy of the inductor L cannot be generated at the output at a given time, crosstalk occurs that affects the adjacent output voltage, and the output requires more energy as in T7. In this case, the inductor current is increased and the interference becomes more severe. Therefore, it is difficult to operate the operating range with CCM and has to operate with DCM only. In order to reduce the interference in the CCM, a method of connecting a separate switch across the inductor L and allowing a free wheeling of the inductor energy to increase the overall inductor current has been reported. Not only is it not easy, but there is a problem in that it still has the disadvantages of operating with DCM.

In addition, according to the control structure of the prior art, each switch must be controlled independently to generate each output voltage. In other words, it is determined whether each output voltage of the boost converter is at a desired voltage level to find an error, and then control the pulse width of the switch M1 to generate the next output in the direction of minimizing the error so that energy is accumulated in the inductor L. PI control that adjusts the (build-up) time for each channel. According to the conventional control method, N PI control is required to generate N outputs, which increases the complexity of the control structure with the number of outputs.

The present invention for solving this problem is to reduce the output ripple noise of the DC / DC converter.

In addition, the present invention aims to alleviate the constraint that the DC / DC converter should be operated only with DCM to eliminate interference between channels, which is a disadvantage of the prior art, so that the DC / DC converter operates stably in DCM and CCM. do.

In addition, an object of the present invention is to improve the problem that the complexity of the control circuit increases as the number of outputs of the DC / DC converter increases.

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In order to achieve the above technical problem, a DC / DC converter according to the present invention is installed between an inductor unit in which energy according to an input voltage is charged, and the inductor unit and a base voltage source, thereby controlling that the energy is charged in the inductor unit. And an output unit for outputting the energy charged in the inductor unit to output terminals electrically connected to each of the output switches through switching of output switches connected in parallel to the inductor unit. A comparison unit configured to compare the feedback voltages of the output voltages through resistors with preset reference voltages and output comparison signals according to the difference between the feedback voltages and the reference voltages; and an amount of current flowing in the inductor unit. Current sensing unit for sensing and the signal output from the comparison signal and the current sensing unit Depending controls the charge switch, and a control unit that controls the output switch in accordance with the comparison signal.
The output unit may include a unit constant voltage output unit, and the unit constant voltage output unit may include an output capacitor unit installed between a corresponding output switch and ground, and two resistors connected in series with each other in parallel with the output capacitor unit.
The output unit further includes a unit negative voltage output unit, wherein the unit negative voltage output unit has a charging capacitor unit electrically connected at one end to a corresponding output switch, an anode is electrically connected to the other end of the charging capacitor unit, and a cathode is connected to ground. An electrically connected communication diode, a reverse current blocking diode having a cathode electrically connected to the other end of the charging capacitor portion, and an anode electrically connected to a corresponding output terminal, and an output capacitor provided between the anode and the ground of the reverse current blocking diode. It is preferable to include two resistors connected in series with each other and in series with the output capacitor.
Preferably, the last comparator among the comparators included in the comparator is a PI controller.
The controller may control the turn-on time of the charging switch according to the comparison signal output from the PI controller.
The charging switch may be turned on to charge the inductor unit, and the output switches included in the unit constant voltage output unit may be sequentially turned on to supply energy charged in the inductor unit to the output terminal of the unit constant voltage output unit.
It is preferable that the last output switch of the output switches is turned off when there is no current flowing in the inductor unit.
The charging switch and the output switch included in the unit negative voltage output unit are turned on to charge the inductor unit and the charging capacitor unit included in the unit negative voltage output unit, and the output switches included in the unit negative voltage output unit are sequentially It is preferable to turn on to supply a voltage according to the voltage difference between the output capacitor unit and the charging capacitor unit to the output terminal.
It is preferable that the last output switch of the output switches included in the unit negative voltage output unit is turned off when there is no current flowing in the inductor unit.
Preferably, the resonance current prevention switch unit is provided between both terminals of the inductor unit, and the resonance current prevention switch unit is turned on when there is no current flowing in the inductor unit.
Preferably, the inductor unit has two or more inductors connected in series.
Preferably, the inductor unit has two or more inductors connected in parallel.
Preferably, the inductor unit has three or more inductors connected in series and in parallel.
The PI controller is preferably controlled by the current control method.
The PI controller is preferably controlled by a voltage control method.
FIG. 3 is a representative block diagram of a non-isolated multi-output boost converter for explaining a DC / DC converter according to a first embodiment of the present invention, and FIG. 4 generates three outputs with the non-isolated multi-output boost converter of FIG. 3. The operation timing diagram at the time of making it make.
Referring to FIG. 3, the DC / DC converter according to the first embodiment of the present invention is provided between an inductor part L, which is charged with energy according to an input voltage Vin, and an inductor part L and a base voltage source. The charge switch unit M1 controls the charging of energy to the inductor unit L, and the output switches S1, ..., which are connected to the inductor unit L in parallel with the energy charged in the inductor unit L. An output unit 31 for outputting to output terminals electrically connected to each of the output switches S1, ..., SN-1, SN through switching of SN-1 and SN, and output to the output terminals Feedback voltages FB 1, ..., FB N-1, FBN, which divide the voltages through the resistor, and preset reference voltages Ref. 1, ..., Ref.N-1, Ref.N By comparing the comparison signal according to the difference between the feedback voltage (FB 1, ..., FB N-1, FBN) and the reference voltages (Ref. 1, ..., Ref.N-1, Ref.N) (Sig 1, ..., Sig N-1, Sig N) outputs the current flowing through the comparator 32 and the inductor (L) The charging switch M1 is controlled and compared according to the current sensing unit and the comparison signals Sig 1, ..., Sig N-1, and Sig N sensing the quantity and the signal T output from the current sensing unit. And a control unit 33 for controlling the output switches S1, ..., SN-1, SN according to the signals Sig1, ..., Sig N-1, Sig N.
The output unit 31 includes a unit constant voltage output unit PO 1, and the unit constant voltage output unit PO 1 includes an output capacitor unit Co 1 and an output capacitor unit provided between the corresponding output switch S1 and ground. It is preferable to include two resistors (Ro11, Ro12) connected in parallel with (Co 1), and in series with each other.
Preferably, the last comparator among the comparators included in the comparator 32 is a PI controller, and the controller 33 controls the turn-on time of the charging switch M1 according to the comparison signal Sig N output from the PI controller. It is preferable. This will be described later with reference to the driving timing diagram of FIG. 4.
It is preferable to further include a resonance current prevention switch unit Sf provided between both terminals of the inductor unit L, and the resonance current prevention switch unit Sf is turned on when there is no current flowing in the inductor unit L. This will also be described later with reference to the driving timing diagram of FIG. 4.
The driving method of the DC / DC converter according to the first embodiment of the present invention will be described in detail with reference to the block diagram of FIG. 3 and the timing diagram of FIG. 4 as follows.

1) The charging switch M1 is turned on to accumulate energy in the inductor part L connected to the input voltage Vin.

2) The charging switch M1 is turned off and the first output switch S1 is turned on to generate a part of the energy stored in the inductor L at the output to Vo (1). Whether the output voltage reaches the desired level is compared with the value divided by the resistor and the reference voltage 1 (ref1) and the comparator 1, when the desired level is reached, the first output switch is turned off.

3) The second output switch S2 is turned on to generate a part of the energy accumulated in the inductor L at the output to Vo (2). Whether the output voltage reaches the desired level is compared with the value divided by the resistor and the reference voltage 2 (ref2) and the comparator 2, when the desired level is reached, the second output switch S2 is turned off.

4) The third output switch S3 is turned on to generate energy remaining in the inductor portion L at the output to Vo (3). The current flowing through the inductor unit L is detected to determine whether all of the energy remaining in the inductor unit L is transferred to the output, and the third output switch S3 is turned off. The third output switch S3 is turned off and the resonance current prevention switch part Sf is turned on by detecting that the current flowing through the inductor L becomes zero. The inductor current (i _L ) is applied to prevent the current from resonating due to the resonance of the parasitic capacitance component seen at the point VN of FIG. 3 and the inductor portion L connected to the input voltage Vin after supplying all the current to the output. Is to cause the resonant current prevention switch unit (Sf) to rotate while flowing.

5) In the above 1) to 4), repeat the operation of paragraph 1) to 4) in one cycle to generate the output voltage at Vo (1), Vo (2), Vo (3). 1), the voltage is generated at Vo (2) and Vo (3). After the output Vo (3) occurs, the resistance of Vo (3) is distributed and compared with the reference voltage 3 (ref3) to find the error so that all the errors in the output Vo (1), Vo (2), and Vo (3) appear together. By controlling the turn-on time of the charging switch M1 through the PI control, the pulse width is adjusted to generate the next output, and the Vo (1) and Vo (2) simply compare the comparable output with the comparator. Only Vo (3) performs PI control, so the control structure is simple. In case of generating N output voltages, the control structure requires only N-1 comparators and 1 PI control.

Analyzing according to the operating frequency of the present invention, when operating the charge switch (M1) at 1MHz it can be seen that the operating frequency of the output switches (S1, S2, S3) also operates at the same 1MHz. Therefore, it can be seen that the output converter is the same as a boost converter that generates less output ripple noise and generates only one output. Even when generating N output voltages, the operating frequencies of the output switches S1, ..., SN are the same as the operating frequency of the charging switch M1.

Figure 5 shows the inductor current in the DCM mode and CCM mode of operation of the boost converter. In DCM mode, there is a zero current flowing through the inductor, while in CCM mode, current is always driven through the inductor to supply more current to the output. The present invention generates a current in the inductor in a waveform similar to a structure that generates one output voltage, so it can operate without problems even in the DCM mode as well as the CCM mode, and does not cause interference in adjacent channels.

6 is a conceptual diagram of a non-isolated multi-output boost type boost converter that generates a positive voltage output and a negative voltage output, which are DC / DC converters according to a second embodiment of the present invention.
Referring to FIG. 6, the DC / DC converter according to the second embodiment of the present invention has a difference in output compared with the DC / DC converter according to the first embodiment of the present invention described above in detail. That is, the output unit 61 included in the DC / DC converter according to the second embodiment of the present invention further includes a unit negative voltage output unit (eg, NO N), and a unit negative voltage output unit (NO N). Is a charge capacitor CN connected at one end to the corresponding output switch SN, an anode is electrically connected to the other end of the charge capacitor CN, and a cathode is electrically connected to ground. 2)), a cathode is electrically connected to the other end of the charging capacitor section CN, and an anode is electrically connected to the corresponding output terminal DN (1), and a reverse current blocking diode DN ( It includes two resistors connected in parallel to the output capacitor unit (CoN) and the output capacitor unit (CoN) provided between the anode and the ground of 1)).
Hereinafter, the differences from the DC / DC converter according to the first embodiment of the present invention will be mainly described.
According to Fig. 6, Vo (1) and Vo (2) are positive voltage outputs and Vo (N-1) and Vo (N) are negative voltage outputs. For example, in the case of generating the negative voltage output Vo (N) in FIG. 6, one end of the charging capacitor CN is electrically connected to the output terminal of the Nth output switch SN, and the other end of the charging capacitor CN is The anode of the communication diode DN (2) and the cathode of the reverse current blocking diode DN (1) are electrically connected, the cathode of the communication diode DN (2) is electrically connected to ground, and the cathode of the reverse current blocking diode DN (1) The anode is electrically connected to the output terminal, and the output capacitor CoN is installed between the anode and the ground of the reverse current blocking diode DN (1), and the two capacitors are connected in parallel with each other in series with the output capacitor CoN. FIG. 7 is an operation timing diagram when one positive voltage output and two negative voltage outputs are generated in FIG. 6 (that is, when N = 3 in FIG. 6). The driving method will be described in detail with reference to the block diagram of FIG. 6 and the timing diagram of FIG. 7 as follows.

1) The charging switch M1 is turned on to accumulate energy for three outputs in the inductor part L connected to the input voltage Vin. Meanwhile, at this time, the second and third output switches S2 and S3 generating the negative voltage output are turned on. A description regarding the turn-on of the second and third output switches S2 and S3 will be described in detail with reference to 5) below.

2) The charging switch M1 is turned off and the first output switch S1 is turned on to generate a part of the energy stored in the inductor L at the output to Vo (1). Whether the output voltage reaches the desired level is compared with the value divided by the resistor and the reference voltage 1 (ref1) and the comparator 1, when the desired level is reached, the first output switch S1 is turned off. As a result, Vo (1) becomes a constant voltage output.

3) When the second output switch S2 is turned on, a part of the energy accumulated in the inductor part L flows to the ground through the charging capacitor C2 and the communication diode D2 (2), and the charging capacitor C2 is charged with energy. Whether the charged voltage has reached the desired level is compared with the divided value through the two resistors connected to the second output switch (S2) and the charging capacitor C2 and the reference voltage (ref2) with the comparator 2 2 Turn off the output switch (S2).

4) The third output switch S3 is turned on so that the current remaining in the inductor part L flows to the ground through the charging capacitor C3 and the communication diode D3 (2), thereby charging energy to the charging capacitor C3. The current flowing through the inductor unit L is detected to determine whether all of the energy remaining in the inductor unit L is transferred to the output, and the third output switch S3 is turned off. The third output switch S3 is turned off by detecting that the current flowing through the inductor L becomes zero, and the resonance current prevention switch part Sf is turned on. Inductor current (i _L ) to supply current to the output to prevent the current from resonating due to the resonance of the inductor section (L) connected to the input voltage (Vin) and the parasitic capacitance component seen at point VN in FIG. Is to cause the resonant current prevention switch unit (Sf) to rotate while flowing.

5) A description will be given regarding the turn-on of the second and third output switches S2 and S3. As in 1), the charging switch M1 is turned on to accumulate the energy required for the output in the inductor part L, and the second and third output switches S2 corresponding to generating the negative voltage output. , S3) is turned on so that the current generated by the voltage difference between the output capacitors Co2, Co3 connected to each output terminal and the charging capacitors C2, C3 connected to one terminal of the second and third output switches S2, S3 Each of the reverse current blocking diodes D2 (1), D3 (1), charging capacitors C2, C3, output switches S2, S3, and charging switch M1 to ground, thereby causing Vo (2) and Vo (3), respectively. Becomes negative voltage output. When the total energy required by Vo (1), Vo (2), and Vo (3) is charged in the inductor unit L, the charge switch M1 is turned off. At this time, the second and third output switches S2 and S3 are also turned off.

6) 1) and 5) above are described for turning on and turning off the second and third output switches S2 and S3 which operate in the same time domain but generate a negative voltage output for convenience of description. 5). The above cycles 1) to 4) operate repeatedly 1) to 4) in one cycle of generating an output voltage at Vo (1), Vo (2) and Vo (3), and output Vo (1), Voltage is generated at Vo (2) and Vo (3). The PI control of the DC / DC converter which generates the positive voltage output and the negative voltage output of the present invention has the last output voltage as in the case of generating the multi-output positive voltage output of FIG. An error is obtained by allocating the generated Vo (3), but the case where Vo (3) generates positive power is the same as that of FIG. 3, thereby generating the multi-output positive power output of FIG. As in the case, the error is obtained by comparing the output voltage with the resistance and the reference voltage (ref3), and as shown in FIG. 6, when Vo (3) generates negative power, the output voltage and the reference voltage ( divide the ref3) into resistances and compare the error to ground to operate the PI controller. The error required to control the PI controller is the sum of the errors from the outputs Vo (1), Vo (2), and Vo (3), and the pulse width is adjusted by controlling the turn-on time of the charging switch M1 through PI control. By doing so, only one PI control is needed as the controller to generate the next output. The boost converter that generates N positive and negative power sources requires only a simple comparator N-1 and one PI controller, and the control structure is similar in complexity to the boost converter that generates one output. .

The present invention has the advantage that the control structure of the non-isolated multi-output boost converter is simple as a control method that compensates for the disadvantages of the prior art. That is, the present invention improves the conventional multi-channel boost converter to control each output side to generate each output voltage. When generating N outputs, only N-1 comparators and one control are required. The advantage is that the control is simple. In addition, the control structure of the conventional method is complicated by the constraints such that the control of each channel should be configured so that there is no interference for each channel, and to prevent the supply of more than a certain current to the output so as not to go into the CCM mode. According to the present invention, by controlling only the last output using the PI controller, there is an advantage that the control structure is simple.

In addition, according to the present invention, the operating frequency of the switch on the output side and the operating frequency of the switch for charging the inductor becomes the same, thereby reducing the output ripple noise.

In addition, since the present invention works well in the DCM mode and CCM mode, it has the advantage of operating stably with a waveform of inductor current similar to the boost converter when generating a single output while controlling multiple outputs.

Claims (25)

delete delete delete delete delete delete delete delete delete delete An inductor unit for charging energy according to an input voltage; A charge switch unit disposed between the inductor unit and a base voltage source to control charging of the energy to the inductor unit; An output unit configured to output energy charged in the inductor unit to output terminals electrically connected to each of the output switches through switching of output switches connected in parallel to the inductor unit; A comparison unit configured to compare the feedback voltages divided through the resistors with the voltages output through the output terminals and predetermined reference voltages, and output comparison signals according to the difference between the feedback voltages and the reference voltages; A current sensing unit sensing an amount of current flowing in the inductor unit; And A control unit controlling the charging switch according to the comparison signals and a signal output from the current sensing unit, and controlling the output switches according to the comparison signals; DC / DC converter comprising a. The method of claim 11, wherein The output unit includes a unit constant voltage output unit, The unit constant voltage output unit An output capacitor unit disposed between the corresponding output switch and ground; And Two resistors connected in parallel to the output capacitor and connected in series; DC / DC converter comprising a. The method of claim 12, The output unit further includes a unit negative voltage output unit, The unit negative voltage output unit A charging capacitor unit having one end electrically connected to a corresponding output switch; A communication diode having an anode electrically connected to the other end of the charging capacitor portion, and a cathode electrically connected to the ground; A reverse current blocking diode having a cathode electrically connected to the other end of the charging capacitor unit, and an anode electrically connected to a corresponding output terminal; An output capacitor unit disposed between the anode and the ground of the reverse current blocking diode; And Two resistors connected in parallel to the output capacitor and connected in series; DC / DC converter comprising a. The method of claim 11, wherein DC / DC converter of the last comparator among the comparators included in the comparator is a PI controller. The method of claim 14, The control unit is a DC / DC converter for controlling the turn-on time of the charging switch in accordance with the comparison signal output from the PI controller. The method of claim 12, Turn on the charging switch to charge the inductor unit, DC / DC converter for sequentially turning on the output switches included in the unit constant voltage output unit to supply the energy charged in the inductor unit to the output terminal of the unit constant voltage output unit. The method of claim 16, DC / DC converter of the output switch is turned off when there is no current flowing in the inductor unit. The method of claim 13, By turning on the output switch included in the charging switch and the unit negative voltage output unit to charge the inductor unit and the charging capacitor unit included in the unit negative voltage output unit, DC / DC converter to sequentially turn on the output switches included in the unit negative voltage output unit to supply the voltage according to the voltage difference between the output capacitor unit and the charging capacitor unit to the output terminal. The method of claim 18, The last output switch of the output switches included in the unit negative voltage output unit is turned off when there is no current flowing in the inductor unit. The method according to any one of claims 11 to 13, Further comprising a resonance current prevention switch unit provided between both terminals of the inductor unit, The resonance current prevention switch unit is turned on when there is no current flowing in the inductor DC / DC converter. The method according to any one of claims 11 to 13, The inductor unit DC / DC converter in which two or more inductors are connected in series. The method according to any one of claims 11 to 13, The inductor unit DC / DC converter in which two or more inductors are connected in parallel. The method according to any one of claims 11 to 13, The inductor unit is a direct current / direct current converter in which three or more inductors are connected in parallel. The method of claim 15, The PI controller is a DC / DC converter controlled by the current control method. The method of claim 15, The PI controller is a DC / DC converter controlled by a voltage control method.

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