JPH0584186U - Current resonance type power supply control circuit - Google Patents

Abstract

(57) [Abstract] [Purpose] To reduce switching loss by always enabling switching elements in a current resonance power supply at optimal timing. [Structure] The primary side of a current resonance type power supply is configured to include a direct current power supply 2, switching elements 3, 4, diodes 5, 6, and a resonance circuit composed of a capacitor 7 and a reactance 8, and a secondary side thereof is a rectifying circuit 9 It is configured to include. The control circuit M includes a current sensor 11 for detecting a resonance current I flowing through the current resonance type power source having the above-described configuration, and the current sensor 11
And the determination circuits 12 and 13 that determine the switching timing of the switching elements 3 and 4 based on the detection signal. The determination circuits 12 and 13 determine whether or not current is flowing through the switching elements 3 and 4 based on the detection signal of the current sensor 11, and only when it is determined that no current is flowing, the ON state of the switching element is determined. Allows switching from to off state.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a control circuit for controlling switching timing of a switching element in a current resonance type power supply.

[0002]

[Prior Art]

 FIG. 5 shows a schematic configuration of a conventional current resonance type power supply. This power supply is an insulation type power supply using a transformer 1, the primary side of which is a DC power supply (including a power supply for rectifying the output of an AC power supply) 2, two switching elements 3 composed of power transistors, 4, a diode 5, 6, and a resonance circuit including a capacitor (C) 7 and a reactance (L) 8 are included, while the secondary side is configured to include a rectifier circuit 9. The DC power supply 2 and the two switching elements 3 and 4 constitute one loop, and diodes 5 and 6 for flowing a current in the opposite direction to these switching elements 3 and 4 are respectively connected in parallel. .. The switching element 4, the capacitor 7, the reactance 8, and the primary winding of the transformer 1 constitute another loop, and the resonance current I flows through this loop.

In the above configuration, when the two switching elements 3 and 4 are alternately switched by the on / off signals A and B shown in FIG. 6 at a predetermined timing, due to the resonance of the capacitor 7 and the reactance 8, as shown in FIG. A resonant current I flows. That is, first, when the on / off signal A rises, the switching element 3 is turned on and a current I (I> 0) begins to flow in the resonance circuit, but when the current I exceeds a certain value, it begins to decrease and becomes zero. After that, the current flows in the reverse direction (I <0) through the diode 5 and then returns to zero. Then, when the on / off signal B rises, the other switching element 4 is turned on, the capacitor 7 charged up to this point starts discharging, and the resonance circuit is switched in the reverse direction via the switching element 4. The current I (I <0) begins to flow, but after that, the direction of the current I switches (I> 0) and returns to zero by the same principle as above. The current I is transmitted to the secondary side through the transformer 1, and the current I ₀ obtained by rectifying the rectifier circuit 9 is supplied to the load 10. By changing the switching timing (switching frequency) of the two switching elements 3 and 4, the duty ratio can be changed and the output voltage V ₀ can be variably controlled.

[0004]

[Problems to be solved by the device]

In the current resonance type power supply having the above-described configuration, the time interval from the rise to the fall of the on / off signals A and B, that is, the on time T of the switching of the switching elements 3 and 4, is the switching elements 3 and 4. It is fixed in advance for a predetermined time so that each of the switching elements 3 and 4 is turned off after the current flowing through the element becomes zero. However, the capacitor (C) 7 and the reactance (L) 8 are likely to change due to temperature and other external factors, and the resonance frequency f _s also changes accordingly. Then, for example, when the resonance frequency f _s of the current I changes as indicated by the broken line in FIG. 6, the current I flows through the switching elements 3 and 4 with the fixed on-time T remaining unchanged. The switching element 3 is turned off in the state (when the switching element 3 is I> 0 and the switching element 4 is I <0), resulting in a problem that the loss at the time of switching increases. In such a case, not only the efficiency of the power source is deteriorated, but also the switching elements 3 and 4 may be thermally damaged.

In view of the above-mentioned conventional problems, the present invention provides a control circuit for a current resonance type power supply, which can reduce switching loss by always enabling switching of a switching element with optimal timing. The purpose is to do.

[0006]

[Means for Solving the Problems]

 The control circuit of the present invention is a current resonance type power supply that outputs a voltage corresponding to the switching frequency by causing a resonance current in the resonance circuit by alternately switching the current from the DC power supply by two switching elements. Used by adding. The configuration of the present invention is characterized by a current sensor for detecting the resonance current and whether or not the resonance current is flowing through the switching element based on the detection signal of the current sensor. And a determination circuit that enables switching of the switching element from the ON state to the OFF state when it is determined that the switching element is not in the ON state.

As the current sensor, a range that does not adversely affect the resonant power supply itself, such as a current sensor that detects a current value from a voltage across a resistor or a CT (current transformer) current sensor that can detect a current in a non-contact manner Various types can be adopted within.

The determination circuit may be configured by a digital circuit or an analog circuit, and various concrete circuit configurations can be considered.

[0009]

[Action]

 In the present invention, the resonance current is constantly detected by the current sensor, and the switching of the switching element from the ON state to the OFF state is enabled only when the current does not flow in the switching element. That is, the on-time of the switching element is not fixed as in the past, but changes appropriately according to the flow of resonance current, and switching from on to off is prohibited when current is flowing through the switching element. .. Therefore, even if the resonance frequency changes due to an external factor, the OFF timing of the switching element changes accordingly, and the switching element is turned OFF after the current stops flowing through the switching element. Therefore, the loss during switching can be suppressed.

[0010]

【Example】

 Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a circuit diagram showing a schematic configuration of a current resonance type power source to which a control circuit M according to an embodiment of the present invention is added. Since the configuration of the current resonance type power source itself is the same as that shown in FIG. 5, its detailed description is omitted here.

As shown in FIG. 1, the control circuit M of this embodiment includes a current sensor 11 for detecting a resonance current I flowing in a current resonance type power supply, and a switching element 3 based on a detection signal of the current sensor 11. 4 and determination circuits 12 and 13 for determining the switching timing.

The current sensor 11 has a structure of a CT type current sensor as shown in FIG. 2, for example, and includes a ferromagnetic core 11a, a winding wire 11b wound around the core 11a, and a winding wire 11b. And a resistor 11c connected in parallel to The magnitude and direction of the current I can be detected from the magnitude and positive / negative of the voltage V across the resistor 11c only by passing the current line through which the resonance current I flows through the core 11a. It is output as a detection signal. The detection signal (voltage V) is positive when the current I flows from the capacitor (C) 7 side toward the reactance (L) 8 side, and is negative when it flows in the opposite direction.

The determination circuits 12 and 13 have, for example, a configuration as shown in FIG. 3, that is, the determination circuit 12 is composed of a comparator 12a and a flip-flop 12b, and the other determination circuit 13 also has a comparator 13a. It is composed of a flip-flop 13b. The detection signal (voltage V) of the current sensor 11 is input to the negative input terminal (-) of the comparator 12a and the positive input terminal (+) of the comparator 13a and compared with the ground potential. On-set timing input signals ON _A and ON _B that determine the ON timings of the switching elements 3 and 4 are input to the set input terminals S of the flip-flops 12b and 13b. At the reset input terminals R of the flip-flops 12b and 13b, output signals of the comparators 12a and 12b are provided as off-timing signals OFF _A and OFF _B that determine the timing of turning off the switching elements 3 and 4, respectively. Is entered. The output terminals Q of the flip-flops 12b and 13b output ON / OFF signals A and B for controlling ON / OFF of the switching elements 3 and 4, respectively, and these are respectively control signals of the switching elements 3 and 4. Input to the terminal.

The operation of the current resonance type power supply to which the control circuit M having the above configuration is added will be described below with reference to FIG. First, an on-timing signal ON _A is output from a CPU (not shown) or the like, and when this is input to the set input terminal S of the flip-flop 12b of the determination circuit 12, the flip-flop 12b is set and output from its output terminal Q. The on signal A rises, and the switching element 3 is turned on. Then, the resonance current I (I> 0) begins to flow through the switching element 3, then starts to decrease when it exceeds a certain value, and after reaching zero, does not flow through the switching element 3 and passes through the diode 5. Flow in the opposite direction (I <0) and then return to zero. At this time, the current I is always detected by the current sensor 11, and when the detection signal (voltage V) becomes negative, that is, the current I begins to flow in the reverse direction via the diode 5, and the switching element 3 When the current stops flowing (when I <0), the off-timing signal OFF _A, which is the output signal of the comparator 12a of the judgment circuit 12, rises, which resets the flip-flop 12b to turn on / off the signal. A falls, so that the switching element 3 is turned off. In this way, the determination circuit 12 determines whether or not the current is flowing through the switching element 3 based on the detection signal of the current sensor 11, and when the current is not flowing, the switching element 3 can be turned off. Control to

Subsequently, when the other on-timing signal ON _B is output and input to the set input terminal S of the flip-flop 13 b of the determination circuit 13, the flip-flop 13 b is set and output from its output terminal Q. The ON signal B which is present rises, whereby the other switching element 4 is turned on. Then, the capacitor 7 charged so far starts discharging, and the resonance current I (I <0) starts to flow through the switching element 4. After that, when it exceeds a certain value, the resonance current I starts to decrease and becomes zero. Does not flow through the switching element 4 but flows in the reverse direction (I> 0) through the diode 6 and then returns to zero. Also at this time, the current I is always detected by the current sensor 11, and when the detection signal (voltage V) changes from negative to positive, that is, the current I starts to flow in the reverse direction via the diode 6, When the current stops flowing to the switching element 4 (when I> 0), the off-timing signal OFF _B, which is the output signal of the comparator 13a of the determination circuit 13, rises, whereby the flip-flop 13b is reset and turned on. The off signal B falls, so that the switching element 4 is turned off. As described above, the determination circuit 13 also determines whether or not current is flowing through the switching element 4 based on the detection signal of the current sensor 11 as in the case of the determination circuit 12, and when it is determined that no current is flowing, switching is performed. Control is performed so that the element 4 can be turned off.

The current I thus obtained is transmitted to the secondary side through the transformer 1 and rectified by the rectifying circuit 9 as in the conventional case shown in FIG. The current I ₀ is supplied to the load 10.

As described above, by adding the control circuit M of this embodiment to the conventional current resonance type power supply, the resonance current I is always detected by the current sensor 11 and the switching elements 3 and 4 are detected. Only when no current is flowing, the switching elements 3 and 4 can be switched from the ON state to the OFF state. Therefore, even if the capacitor (C) 7 and the reactance (L) 8 change due to temperature and other external factors and the resonance frequency changes accordingly, the switching elements 3 and 4 are turned off accordingly. The timing is changed appropriately and the switching element is turned off after the current stops flowing through the switching elements 3 and 4. Therefore, it is possible to reliably prevent the switching elements from turning off within the period in which the current is flowing through the switching elements 3 and 4, and as a result, the loss during switching is suppressed to prevent thermal damage to the switching elements and power supply efficiency. It can prevent the deterioration.

As described above, as the current sensor, other than the CT type current sensor used in the above-mentioned embodiment, various types can be adopted within a range not adversely affecting the resonance type power source itself. is there. The current to be detected by the current sensor does not have to be the current itself flowing through the resonance circuit as in the above embodiment, but the current flowing through the loop on the DC power supply side may be detected, or the transformer may be used. It is also possible to detect the current on the secondary side of the.

The determination circuit is not limited to the one used in the above embodiment, and various configurations capable of appropriately controlling the switching timing based on the detection signal of the current sensor can be adopted. is there.

Further, the control circuit of the present invention can be applied not only to the insulated type current resonance type power source using the transformer as shown in the above embodiment but also to the non-insulated type without using the transformer. ..

[0021]

[Effect of the device]

 According to the present invention, even if the resonance frequency changes due to an external factor, by appropriately changing the timing of turning off the switching element in response to the change, the switching element can be switched within the period in which the current is flowing. It is possible to prevent the element from turning off, and as a result, it is possible to suppress element loss during switching. Therefore, it is possible to prevent the heat damage of the switching element and the deterioration of the power supply efficiency.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing a schematic configuration of a current resonance type power source to which a control circuit M according to an embodiment of the present invention is added.

FIG. 2 is a diagram showing an example of a current sensor used in a control circuit M of the same embodiment.

FIG. 3 is a diagram showing an example of a determination circuit used in the control circuit M of the embodiment.

FIG. 4 is a timing chart showing an operation of the current resonance type power supply to which the control circuit M of the embodiment is added.

FIG. 5 is a circuit diagram showing a schematic configuration of a conventional current resonance type power supply.

FIG. 6 is a timing chart showing the operation of a conventional current resonance type power supply.

[Explanation of symbols]

 1 Transformer 2 DC Power Supply 3, 4 Switching Element 5, 6 Diode 7 Capacitor (C) 8 Reactance (L) 9 Rectifier Circuit 11 Current Sensor 12, 13 Judgment Circuit 12a, 13a Comparator 12b, 13b Flip Flop M Control Circuit

Claims (1)

[Scope of utility model registration request] 1. A current resonance type power supply for producing a resonance current in a resonance circuit by alternately switching a current from a DC power supply by two switching elements and outputting a voltage corresponding to the switching frequency, A current sensor that detects the resonance current, and determines whether or not a current is flowing through the switching element based on a detection signal of the current sensor, and determines from the ON state of the switching element when it is determined that no current is flowing. A control circuit for a current resonance type power supply, comprising: a determination circuit capable of switching to an off state.