JP3200879U - Improved power switch control circuit - Google Patents

Abstract

An improved power switch control circuit having good conversion efficiency for a green energy power source (for example, solar energy) having a large voltage fluctuation range. A first opening / closing unit 104, a second opening / closing unit 106, a third opening / closing unit 108, a fourth opening / closing unit 110 and an opening / closing control unit 112 are included. When the DC voltage supply device 20 transmits a DC voltage, the switching control unit turns on the fourth switching unit and turns off the second switching unit, and after delaying the first predetermined time, the switching control unit The opening / closing unit is turned on and the third opening / closing unit is turned off. When the DC voltage supply device stops the transmission of the DC voltage, the switching control unit turns on the third switching unit, turns off the first switching unit, delays the second predetermined time, and then opens and closes the switching control unit. Turn on the 2 open / close unit and turn off the 4th open / close unit. [Selection] Figure 1

Description

  The present invention relates to an improved power switch control circuit, and more particularly to an improved power switch control circuit in which an input DC voltage is lower than a super capacitor voltage.

  The power conversion control circuit of the prior art is applied to a DC voltage supply device, a super capacitor and a power load (or power processing circuit), and the DC voltage supply device transmits a DC voltage via the power conversion control circuit of the prior art. When the power supply load (power supply processing circuit) is powered and the DC voltage supply device stops transmission of the DC voltage, the super capacitor is connected to the power supply load (or power supply processing circuit) via the power conversion control circuit of the prior art. To supply power.

  The above-mentioned defect of the prior art is that the DC voltage needs to be higher than the voltage of the supercapacitor, otherwise the supercapacitor and the prior art power switch control circuit cannot operate normally. Here, a problem occurs when applied to a green energy power source (for example, solar energy). This is because the voltage of the green energy power supply is relatively low in some cases (for example, the sunlight is relatively weak) and lower than the supercapacitor voltage. The overall conversion efficiency is not good.

JP 7-184320 A

  In order to improve the above-mentioned defects of the prior art, an object of the present invention is to provide an improved power switch control circuit having a good conversion efficiency for a green energy power source (eg, solar energy) having a large voltage fluctuation range. is there.

To achieve the above object of the present invention, the improved power switch control circuit of the present invention is applied to a DC voltage supply device and a super capacitor, and the improved power switch control circuit is electrically connected to the DC voltage supply device. A voltage input terminal; a first switching unit electrically connected to the voltage input terminal; a second switching unit electrically connected to the supercapacitor; a third switching unit electrically connected to the second switching unit; A fourth opening / closing unit electrically connected to the unit, the voltage input terminal, the first opening / closing unit, the second opening / closing unit, the third opening / closing unit, and an opening / closing control unit electrically connected to the fourth opening / closing unit; An open / close unit and a voltage output terminal electrically connected to the fourth control unit.
Among these, when the DC voltage supply device transmits a DC voltage to the voltage input terminal, the switching control unit turns on the fourth switching unit and turns off the second switching unit. Subsequently, after delaying the first predetermined time, the opening / closing control unit turns on the first opening / closing unit and turns off the third opening / closing unit. Among them, when the DC voltage supply device stops transmitting the DC voltage to the voltage input terminal, the switching control unit turns on the third switching unit and turns off the first switching unit. Subsequently, after delaying the second predetermined time, the opening / closing control unit turns on the second opening / closing unit and turns off the fourth opening / closing unit.

  In order to achieve the other object of the present invention, the improved power switch control circuit of the present invention is applied to a DC voltage supply device and a super capacitor, and the improved power switch control circuit is applied to the DC voltage supply device. A voltage input terminal to be electrically connected; a first switching unit electrically connected to the voltage input terminal; a second switching unit electrically connected to the supercapacitor; a third switching unit electrically connected to the second switching unit; An open / close control unit electrically connected to the voltage input terminal, the first open / close unit, the second open / close unit, and the third open / close unit; a voltage output terminal electrically connected to the first open / close unit and the third open / close unit; ,including. Among them, when the DC voltage supply device transmits a DC voltage to the voltage input terminal, the switching control unit turns off the second switching unit, and then, after delaying a first predetermined time, the switching control unit The first opening / closing unit is turned on, and the third opening / closing unit is turned off. When the DC voltage supply device stops transmitting the DC voltage to the voltage input terminal, the switching control unit turns on the third switching unit and turns off the first switching unit. . Subsequently, after delaying the second predetermined time, the opening / closing control unit turns on the second opening / closing unit.

  The effect of the present invention is that the input current voltage can be made lower than the voltage of the super capacitor, and therefore, it is possible to have a good conversion efficiency for a green energy power source (for example, solar energy) having a large voltage fluctuation range. .

1 is a block diagram of a first embodiment of an improved power conversion control circuit according to the present invention; FIG. It is a block diagram of 2nd Example of the improved power supply conversion control circuit of this invention.

  The details and technical contents of the present invention will be described below with reference to the drawings. However, the drawings are merely used for reference and description, and do not limit the present invention.

  Referring to FIG. 1, it is a block diagram of a first embodiment of the improved power switch control circuit of the present invention. The improved power switch control circuit 10 is applied to the DC voltage supply device 20 and the super capacitor 30. The improved power switch control circuit 10 includes a voltage input terminal 102, a first opening / closing unit 104, a second opening / closing unit 106, a second 3 open / close unit 108, fourth open / close unit 110, open / close control unit 112, voltage output terminal 114, first resistor 116, second resistor 118, third resistor 120, and fourth resistor 122. The switching control unit 112 includes a voltage comparison subunit 11202, a delay subunit 11204, a logic gate unit 11206, and a down subunit 11208.

  The voltage input terminal 102 is electrically connected to the DC voltage supply device 20. The first opening / closing unit 104 is electrically connected to the voltage input terminal 102. The second opening / closing unit 106 is electrically connected to the super capacitor 30. The third opening / closing unit 108 is electrically connected to the second opening / closing unit 106. The fourth opening / closing unit 110 is electrically connected to the first opening / closing unit 104. The switching control unit 112 is electrically connected to the voltage input terminal 102, the first switching unit 104, the second switching unit 106, the third switching unit 108, and the fourth switching unit 110. The voltage output terminal 114 is electrically connected to the third opening / closing unit 108 and the fourth opening / closing unit 110.

The first resistor 116 is connected to a source and a gate of the first opening / closing unit 104. The second resistor 118 is connected to the source and gate of the second opening / closing unit 106. The third resistor 120 is connected to the source and gate of the third opening / closing unit 108. The fourth resistor 122 is connected to the source and gate of the fourth open / close unit 110. The voltage comparison subunit 11202 is electrically connected to the voltage input terminal 102.
The delay subunit 11204 is electrically connected to the voltage comparison subunit 11202. The logic gate unit 11206 is electrically connected to the voltage comparison subunit 11202 and the delay subunit 11204. The down subunit 11208 is electrically connected to the logic gate unit 11206, the first opening / closing unit 104, the second opening / closing unit 106, the third opening / closing unit 108, and the fourth opening / closing unit 110.

  The DC voltage supply device 20 inputs the DC voltage 22 to the voltage input terminal 102, and when the DC voltage 22 conforms to the standard voltage range, the switching control unit 112 turns on the fourth switching unit 110. And turning off the second switching unit 106, thereby avoiding that the supercapacitor 30 is recharged by a relatively high voltage (ie, avoiding back flow to the supercapacitor 30); When the supercapacitor 30 is recharged with a relatively high voltage, the supercapacitor 30 is damaged, and a danger is generated. Subsequently, after delaying the first predetermined time, the opening / closing control unit 112 turns on the first opening / closing unit 104 and turns off the third opening / closing unit 108. By turning on the first open / close unit 104, it is possible to prevent the open / close MOS internal diode from stepping down and causing heat generation and unnecessary power consumption.

  When the DC voltage supply device 20 stops transmitting the DC voltage 22 to the voltage input terminal 102, the open / close control unit 112 turns on the third open / close unit 108 and the first open / close unit 104. Is turned off, and the output voltage of the voltage output terminal 114 is prevented from decreasing (that is, the power output of the voltage output terminal 114 is avoided), and the backflow to the DC voltage supply device 20 is avoided at the same time. Subsequently, after delaying the second predetermined time, the opening / closing control unit 112 turns on the second opening / closing unit 106 and turns off the fourth opening / closing unit 110. By turning on the second open / close unit 106, it is possible to prevent the open / close MOS internal diode from stepping down and causing heat generation and unnecessary power consumption.

  The first opening / closing unit 104 is a P-type MOSFET, the second opening / closing unit 106 is a P-type MOSFET, the third opening / closing unit 108 is a P-type MOSFET, and the fourth opening / closing unit 110 is It is a P-type MOSFET. The voltage output 114 is connected to a power load (not shown in FIG. 1) or a power processing circuit (not shown in FIG. 1), and the down subunit 11208 includes at least one N-type MOSFET (in FIG. 1). Not shown).

  Referring to FIG. 2, it is a block diagram of a second embodiment of the improved power switch control circuit of the present invention. The improved power switch control circuit 10 is applied to the DC voltage supply device 20 and the super capacitor 30. The improved power switch control circuit 10 includes a voltage input terminal 102, a first opening / closing unit 104, and a second opening / closing unit 106. A third opening / closing unit 108, an opening / closing control unit 112, a voltage output terminal 114, a first resistor 116, a second resistor 118, and a third resistor 120. The switching control unit 112 includes a voltage comparison subunit 11202, a delay subunit 11204, a logic gate unit 11206, and a down subunit 11208.

  The voltage input terminal 102 is electrically connected to the DC voltage supply device 20. The first opening / closing unit 104 is electrically connected to the voltage input terminal 102. The second opening / closing unit 106 is electrically connected to the super capacitor 30. The third opening / closing unit 108 is electrically connected to the second opening / closing unit 106. The opening / closing control unit 112 is electrically connected to the voltage input terminal 102, the first opening / closing unit 104, the second opening / closing unit 106, and the third opening / closing unit 108. The voltage output terminal 114 is electrically connected to the first opening / closing unit 104 and the third opening / closing unit 108.

  The first resistor 116 is connected to the source and gate of the first opening / closing unit 104. The second resistor 118 is connected to the source and gate of the second opening / closing unit 106. The third resistor 120 is connected to the source and gate of the third opening / closing unit 108. The voltage comparison subunit 11202 is electrically connected to the voltage input terminal 102. The delay subunit 11204 is electrically connected to the voltage comparison subunit 11202. The logic gate unit 11206 is electrically connected to the voltage comparison subunit 11202 and the delay subunit 11204. The down subunit 11208 is electrically connected to the logic gate unit 11206, the first opening / closing unit 104, the second opening / closing unit 106, and the third opening / closing unit 108.

  The DC voltage supply device 20 transmits the DC voltage 22 to the voltage input terminal 102, and when the DC voltage 22 matches the standard voltage range, turns off the switching control unit 112 and the second switching unit 106, Avoiding the supercapacitor 30 from being recharged by a relatively high voltage (ie, avoiding backflow to the supercapacitor 30) and recharging the supercapacitor 30 by a relatively high voltage; The supercapacitor 30 is damaged, and a danger is caused. Subsequently, after delaying the first predetermined time, the opening / closing control unit 112 turns on the first opening / closing unit 104 and turns off the third opening / closing unit 108. By turning on the first open / close unit 104, it is possible to prevent the open / close MOS internal diode from stepping down and causing heat generation and unnecessary power consumption.

  When the DC voltage supply device 20 stops transmitting the DC voltage 22 to the voltage input terminal 102, the open / close control unit 112 turns on the third open / close unit 108 and the first open / close unit 104. Is turned off, and the output voltage of the voltage output terminal 114 is prevented from decreasing (that is, the power output of the voltage output terminal 114 is avoided), and the backflow to the DC voltage supply device 20 is avoided at the same time. Subsequently, after delaying the second predetermined time, the opening / closing control unit 112 turns on the second opening / closing unit 106. By turning on the second open / close unit 106, it is possible to prevent the open / close MOS internal diode from stepping down and causing heat generation and unnecessary power consumption.

  The first opening / closing unit 104 is a P-type MOSFET, the second opening / closing unit 106 is a P-type MOSFET, and the third opening / closing unit 108 is a P-type MOSFET. The voltage output 114 is connected to a power load (not shown in FIG. 2) or a power processing circuit (not shown in FIG. 2), and the down subunit 11208 includes at least one N-type MOSFET (in FIG. 2). Not shown).

  The effect of the present invention is that the input current voltage can be made lower than the voltage of the super capacitor, and therefore, it is possible to have a good conversion efficiency for a green energy power source (for example, solar energy) having a large voltage fluctuation range. .

  In the present invention, the preferred embodiments have been disclosed as described above. However, the present invention is not limited to the present invention, and anyone who is familiar with the technology can make an equivalent range without departing from the spirit and scope of the present invention. Of course, various fluctuations and hydration colors can be added.

10 improved power conversion control circuit 20 DC power switch control circuit 22 DC voltage 30 super capacitor 102 voltage input terminal 104 first switching unit 106 second switching unit 108 third switching unit 110 fourth switching unit 112 switching control unit 114 voltage output Terminal 116 first resistor 118 second resistor 120 third resistor 122 fourth resistor 11202 voltage comparison subunit 11204 delay subunit 11206 logic gate subunit 11208 down subunit

Claims (10)

An improved power switch control circuit applied to a DC voltage supply device and a super capacitor, the improved power switch control circuit,
A voltage input terminal electrically connected to the DC voltage supply device;
A first switching unit electrically connected to the voltage input end;
A second switching unit electrically connected to the super capacitor;
A third opening / closing unit electrically connected to the second opening / closing unit;
A fourth opening / closing unit electrically connected to the first opening / closing unit;
An open / close control unit electrically connected to the voltage input terminal, the first open / close unit, the second open / close unit, the third open / close unit, and the fourth open / close unit;
A voltage output terminal electrically connected to the third switching unit and the fourth switching unit;
Of which, when the DC voltage supply device transmits a DC voltage to the voltage input terminal, the open / close control unit turns on the fourth open / close unit, and turns off the second open / close unit,
Subsequently, after delaying the first predetermined time, the opening / closing control unit turns on the first opening / closing unit and turns off the third opening / closing unit. Among them, when the DC voltage supply device stops transmitting the DC voltage to the voltage input terminal, the switching control unit turns on the third switching unit and turns off the first switching unit. Subsequently, after delaying a second predetermined time, the open / close control unit turns on the second open / close unit and turns off the fourth open / close unit. A first resistor connected to the first open / close unitary source and gate;
A second resistor connected to the second open / close unitary source and gate;
A third resistor connected to the third open / close unitary source and gate;
A fourth resistor connected to the fourth open / close unitary source and gate;
The improved power switch control circuit of claim 1 further comprising: The opening / closing control unit includes:
A voltage comparison subunit electrically connected to the voltage input;
A delay subunit electrically connected to the voltage comparison subunit;
The improved power switch control circuit of claim 2 further comprising: The opening / closing control unit includes:
A logic gate unit electrically connected to the voltage comparison subunit and the delay subunit;
A down-subunit electrically connected to the logic gate unit, the first opening / closing unit, the second opening / closing unit, the third opening / closing unit, and the fourth opening / closing unit;
The improved power switch control circuit of claim 3 further comprising:   The first opening / closing unit is a P-type MOSFET, the second opening / closing unit is a P-type MOSFET, the third opening / closing unit is a P-type MOSFET, and the fourth opening / closing unit is a P-type MOSFET. The improved power switch control circuit according to claim 4. An improved power switch control circuit applied to a DC voltage supply device and a super capacitor, the improved power switch control circuit,
A voltage input terminal electrically connected to the DC voltage supply device;
A first switching unit electrically connected to the voltage input end;
A second switching unit electrically connected to the super capacitor;
A third opening / closing unit electrically connected to the second opening / closing unit;
An open / close control unit electrically connected to the voltage input terminal, the first open / close unit, the second open / close unit, and the third open / close unit;
A voltage output terminal electrically connected to the first switching unit and the third switching unit;
Of which, when the DC voltage supply device transmits a DC voltage to the voltage input terminal, the open / close control unit turns on the fourth open / close unit, and turns off the second open / close unit,
Subsequently, after delaying the first predetermined time, the opening / closing control unit turns on the first opening / closing unit and turns off the third opening / closing unit. Among them, when the DC voltage supply device stops transmitting the DC voltage to the voltage input terminal, the switching control unit turns on the third switching unit and turns off the first switching unit. Subsequently, after delaying a second predetermined time, the open / close control unit turns on the second open / close unit. A first resistor connected to the first open / close unitary source and gate;
A second resistor connected to the second open / close unitary source and gate;
A third resistor connected to the third open / close unitary source and gate;
The improved power switch control circuit of claim 6 further comprising: The opening / closing control unit includes:
A voltage comparison subunit electrically connected to the voltage input;
A delay subunit electrically connected to the voltage comparison subunit;
The improved power switch control circuit of claim 7 further comprising: The opening / closing control unit includes:
A logic gate unit electrically connected to the voltage comparison subunit and the delay subunit;
A down subunit electrically connected to the logic gate unit, the first opening / closing unit, the second opening / closing unit, the third opening / closing unit;
The improved power switch control circuit of claim 8 further comprising:   The improved power switch control circuit according to claim 9, wherein the first switching unit is a P-type MOSFET, the second switching unit is a P-type MOSFET, and the third switching unit is a P-type MOSFET. .

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