KR101342863B1 - Using a free voltage solar modules power supplies - Google Patents

Abstract

The present invention relates to a power supply device in a free voltage method using a photovoltaic module. The present invention charges an emergency battery through a battery charging unit by switching an input voltage after removing noise from the input voltage through a noise filter unit at DC 200-850 V using a photovoltaic module, and supplies power to various devices (voltmeter, ammeter, temperature sensor, etc.) at the same time. The power supply device comprises a power switching circuit unit for supplying the input voltage at DC 200-850 V without noise to a PWM controller; the PWM controller for modulating the pulse width of the start power of the power switching circuit unit; a driver for driving a drive switching circuit unit maintaining a constant voltage outputted from the PWM controller; the drive switching circuit unit driven by the driver; a transformer for supplying the output voltage of the drive switching circuit unit to a rectification and voltage detection circuit unit; the rectification and voltage detection circuit unit for supplying power to a load side by being connected to the secondary side of the transformer; and a feedback signal unit for supplying feedback signals by being interposed between the rectification and voltage detection circuit unit and the PWM controller.

Description

Using a free voltage solar modules power supplies

The present invention relates to a power supply device of a pre-voltaic method using a solar module, and more particularly, a constant DC voltage is output by outputting an input DC voltage having a high fluctuation range input from the solar module as a stable DC voltage. It is for supplying power to voltmeter, ammeter, temperature sensor, etc.

In general, a power supply device using a solar module adopts a method of charging an emergency battery using solar light collected from the solar module.

Such a power supply device uses a voltage charged in a battery in an emergency, converts a direct current voltage into an alternating voltage, and uses it for general load power supply, or by using a converter while switching the input direct voltage using a relay. It is used as lighting load with DC power. However, the input voltage input from the solar module is DC 200V ~ 800V, the voltage fluctuation range is very large. That is, since the solar light collected in a state in which a plurality of solar modules are connected in parallel and in parallel is affected by the surrounding environment or weather, the input voltage is generally DC 200V to 850V, and the voltage fluctuation range is very large.

In order to receive a constant voltage which is secured by using such a large fluctuation voltage as an input voltage, a relay-type power supply device is adopted as in Korean Patent No. 10-1193499.

The power supply device based on the relay method uses a voltage with a large fluctuation characteristic of the solar module as an input voltage, so when used as a power supply for a voltmeter, an ammeter, a temperature sensor, etc. in a distribution panel connected to a solar module requiring a constant DC voltage. Because the input voltage is not constant, it cannot be used for the devices such as the voltmeter, ammeter, temperature sensor, etc., and even if it is used, the operation may not be performed smoothly due to the change of the input voltage. do. In order to solve this problem, a separate stabilized power supply is required when using a power supply such as a voltmeter, an ammeter, or a temperature sensor in a distribution panel connected to a solar module requiring a constant DC voltage. Is pointed out.

The present invention provides a stable and constant DC power source obtained from the sun and the module to a device such as a voltmeter, an ammeter, a temperature sensor, etc. by maintaining a constant voltage required even when a voltage having a large fluctuation specific to the solar module is used as an input voltage. It is a technical object of the present invention to enable the use of a device without a power supply device for operation of the device, and to enable the device to operate without a malfunction despite a large input voltage.

The present invention is a DC 200V ~ 850V using a solar module to switch the input voltage through the noise filter to remove the noise and then to charge the emergency battery through the battery charging unit and at the same time power to various devices (voltmeter, ammeter, temperature sensor, etc.) In the supply, the power switching circuit for supplying the input voltage to the PWM controller at 200V ~ 850V DC noise is removed; A PWM controller configured to pulse width modulate a start power supply of the power switching circuit unit; A driver for driving a driving switching circuit part for maintaining a constant voltage output from the PWM controller; A drive switching circuit unit driven by the driver; A transformer for supplying an output voltage of the driving switching circuit part to a rectification and voltage sensing circuit part side; A rectification and voltage sensing circuit unit connected to the transformer secondary side to supply power to the load side; And a feedback signal unit for supplying a feedback signal between the rectifying and voltage sensing circuit unit and the PWM controller.

The present invention provides a stable and constant voltage to a device such as a voltmeter, an ammeter, a temperature sensor, etc. by using a free voltage method even when a voltage having a large fluctuation from the solar module is an input voltage. It has the effect of enabling the use of the device without a power supply and the smooth operation without a malfunction, it is possible to supply a stabilized standard power without the separate power supply has the effect of significantly reducing the cost.

 In particular, the present invention can reliably supply DC power supply to devices such as voltmeters, ammeters or temperature sensors that require a constant DC power supply, and greatly increase the utilization of the input DC voltage obtained from the solar module. Has the effect.

1 is a circuit block diagram of the present invention
2 is a detailed circuit diagram of the present invention.

The present invention is a DC 200V ~ 850V using a solar module not shown to switch the input voltage through the noise filter unit 10 after removing the noise to charge the emergency battery 30 through the battery charging unit 20 and at the same time In supplying the DC voltage obtained from the photovoltaic module to the DC power supply of various devices (voltmeter, ammeter, temperature sensor, etc.), the power for supplying the input voltage to the PWM controller at DC 200V ~ 850V with the noise removed A switching circuit section 40; A PWM controller 50 for pulse width modulating the start power of the power switching circuit 40; A driver (60) for driving a driving switching circuit unit for maintaining a constant voltage output from the PWM controller (50); A drive switching circuit unit 70 driven by the driver 60; A transformer (80) for supplying the output voltage of the driving switching circuit unit (70) to the rectification and voltage sensing circuit unit side; A rectification and voltage sensing circuit unit 90 connected to the transformer 80 for supplying power to the load side; And a feedback signal unit 100 for supplying a feedback signal between the rectifying and voltage sensing circuit unit 90 and the PWM controller 50.

In the above, the power switching circuit unit 40 is connected between the FET Q5 driven by the filtered voltage B + through the noise filter unit 10 and the transistor Q7 connected to the gate of the FET Q5. Connect a cathode of the zener diode Z3 to the resistor R27, a charge capacitor C16, C12, and a zener diode Z4 in parallel between the base and the emitter of the transistor Q7. The diodes D14 and D15 are connected to the cathode side of the zener diode Z4 to be used as the power supply VCC of each circuit portion.

The FET Q5 is turned on when the filtered voltage B + is supplied and is output to the power supply VCC terminal side through the drain-source side to supply the operating power to the microprocessor U1 of the PWM controller 50 to supply pulses. Width modulation is performed, and voltage is induced on the secondary (first and second) sides of the transformer T3 through the output terminal of the microprocessor U1 to operate the driver 60 to be described later. Q5) is turned off, thereby turning on the transistor Q7 while a current flows through the collector and emitter to the transistor Q7 side. At this time, the voltage charged in the charging capacitor (C16) (C12) is continuously supplied through the power supply (VCC) terminal side of each circuit portion through the diode (D14) (D15). Therefore, even when the input voltage of DC 200V to 850V having a large fluctuation range obtained from the solar module is supplied, the FET Q5 and the transistor Q7 are turned on and off while operating the PWM controller 50 and at the same time supplying power to each circuit part. Since it is possible to supply the free voltage method will be possible.

As such, when the initial operation start power is supplied to the PWM controller 50 by the power switching circuit unit 40, even if the input voltage of DC 200V to 850V having a large fluctuation range obtained from the solar module is supplied, the PWM controller 50 is irrelevant. ) Is to perform the operation, it will be able to continue to operate by the operation of the feedback signal unit 100 to be described later.

In addition, the drivers 60 for driving the driving switching circuit unit maintaining the constant voltage output from the PWM controller 50 are alternately operated on each of the secondary sides of the transformer T3 (Q3) (Q4). The drive switching circuit unit 70 is formed by connecting the gates of the FETs Q1 and FETs Q2 to the emitter sides of the transistors Q3 and Q4.

Therefore, the pulse width modulated voltage is kept constant by the FET Q1 and the FET Q2, and is provided by the rectification and voltage sensing circuit unit 90 for supplying power to the load side connected to the transformer 80 secondary side. By generating a constant DC power supply (+ 25V in the present invention), it is possible to supply a safe power supply to the device such as a voltmeter, ammeter, temperature sensor. At this time, when the rectification and voltage sensing circuit unit 90 operates, the photo coupler OP1-B and OP1 constituting the feedback signal unit 100 interposed between the rectifying and voltage sensing circuit unit 90 and the PWM controller 50. The microprocessor U1 of the PWM controller 50 operates stably and continuously by the constant voltage fed back by -A).

As described above, in the present invention, even if an input voltage (DC 200V to 850V) having a large fluctuation range input from the solar module is supplied, a constant and stable constant voltage is always supplied to the load side regardless of the variation of the voltage. It is possible to reliably supply DC power supply to devices such as voltmeters, ammeters or temperature sensors that require supply, and to greatly increase the utilization of the input DC voltage obtained from the solar module.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof,

But are not limited to, those of ordinary skill in the art to which the invention pertains

It will be understood that within the scope of the present invention,

It will be appreciated that many variations and applications not illustrated are possible.

And variations relating to these variations and applications are set out in the appended claims

It should be construed as being included in the scope of the present invention as defined.

10; Noise filter unit 20: Battery charging unit
30: battery 40: power switching circuit
50: PWM controller 60: driver
70: drive switching circuit portion 80: transformer
90: rectification and voltage sensing circuit unit 100: feedback signal unit

Claims (4)

DC 200V ~ 850V using the solar module to remove the noise through the noise filter unit 10 after switching to charge the emergency battery 30 through the battery charging unit 20 and at the same time from the solar module In supplying the obtained DC voltage to the DC power supply of various devices (voltmeter, ammeter, temperature sensor, etc.), the power switching circuit section 40 for supplying the input voltage to the PWM controller at DC 200V ~ 850V with the noise removed; ; A PWM controller 50 for pulse width modulating the start power of the power switching circuit 40; A driver (60) for driving a driving switching circuit unit for maintaining a constant voltage output from the PWM controller (50); A drive switching circuit unit 70 driven by the driver 60; A transformer (80) for supplying the output voltage of the driving switching circuit unit (70) to the rectification and voltage sensing circuit unit side; A rectification and voltage sensing circuit unit 90 connected to the transformer 80 for supplying power to the load side; The prevoltage method using a solar module comprising a feedback signal unit 100 for supplying a feedback signal interposed between the rectification and voltage sensing circuit unit 90 and the PWM controller 50. Power supply. 2. The power switching circuit 40 according to claim 1, wherein the power switching circuit section 40 is driven by the filtered voltage B + through the noise filter section 10, and a transistor Q7 connected to the gate of the FET Q5. Is connected to the cathode of the zener diode (Z3), and the resistor (R27), charge capacitor (C16) (C12) and the zener diode (Z4) in parallel between the base and the emitter of the transistor (Q7) However, the pre-voltage power supply using a solar module, characterized in that the diode (D14) (D15) is connected to the cathode side of the zener diode (Z4). The photo coupler (OP1-B) (OP1-A) constituting the feedback signal unit 100 interposed between the rectification and voltage sensing circuit unit 90 and the PWM controller 50 is operated and fed back. Pre-voltage type power supply using a solar module, characterized in that the microprocessor (U1) of the PWM controller 50 is continuously operated by the constant voltage. The power supply apparatus of claim 2, wherein the transistor (Q7) is turned off when the FET (Q5) of the power switching circuit unit (40) operates.

Images