KR101764651B1 - Power applying apparatus and method for controlling connecting photovoltaic power generating apparatus - Google Patents

Abstract

A photovoltaic apparatus-associated power supply apparatus and a control method thereof are disclosed. Embodiments of the present invention provide a power supply apparatus that supplies power generated by a power supply apparatus that supplies power to a load to a load directly to a load or stores it in a battery or supplies energy stored in the battery to a load The system is implemented more simply and the product cost is reduced as the parts are reduced. In addition, since the output of the generated power and / or the energy stored in the battery is directly supplied to the load, not the system, the battery storing the energy when the power failure occurs can be used as the electroless- The stored power can be used more stably.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a photovoltaic power generation apparatus,

The present invention relates to a solar-power-unit-connected power-supply apparatus and a control method thereof, and more particularly to a solar-power-unit-connected power-supply apparatus for supplying power generated from a solar- And a control method.

There is a growing interest in renewable energy due to the depletion of fuels such as oil and environmental degradation. Particularly, interest is growing in the fields of wind power, solar power, and fuel cells as an energy source. When these are used, independent and dedicated power conversion devices and devices for controlling them are manufactured or used.

For example, in the case of using wind power, a load or a power system is connected in series by connecting an AC-DC converter (converter) and a DC-AC converter (DC-AC converter, inverter, inverter) And maximum output point follow-up control to follow the maximum power generated by wind speed and turbine speed.

On the other hand, when a fuel cell or solar light is used, a power conversion device that links a load and a power system using a DC-DC converter (DC-DC converter or DC-DC Booster) and a DC- And a control algorithm for outputting the maximum power that can be obtained according to the operating conditions and the solar radiation conditions and a control device equipped with the control algorithm.

Embodiments of the present invention can be realized by providing the power generation output from the photovoltaic power generation device to the load so as not to undergo conversion to an AC voltage, And an object of the present invention is to provide a power supply apparatus and a control method thereof.

Further, in the embodiments of the present invention, in supplying the generated power output from the photovoltaic device to the load, by directly implementing the output of the generated generated power and / or the energy stored in the battery to the load instead of the grid, Another object of the present invention is to provide a power supply apparatus and a control method thereof, which can operate and simplify the flow of power.

A power supply apparatus according to an embodiment of the present invention is a power supply apparatus that supplies power to a DC load in association with a solar photovoltaic power generation apparatus and converts the generated power output from the solar photovoltaic power generation apparatus into a first direct current voltage, A power conversion unit for converting a generated second direct current voltage stored in the battery according to the generated power and the amount of electric power of the direct current load into the first direct current voltage and rectifying the first direct current voltage to supply the direct current load to the direct current load; A battery for storing the second DC voltage; And a controller for controlling the operation of the power conversion unit.

In an embodiment, the power converter includes: an MPPT converter for boosting power generated from the photovoltaic device and outputting a first DC voltage; A bidirectional converter for converting the first DC voltage into a second DC voltage suitable for the battery or converting a second DC voltage stored in the battery into the first DC voltage according to driving of the controller; And a DC power supply unit provided at an input terminal of the DC load and rectifying a first DC voltage output from at least one of the MPPT converter and the bidirectional converter and supplying the rectified first DC voltage to the DC load.

In the embodiment, the control unit controls the DC power supply unit so that the rectified voltage output from the DC power supply unit is supplied to the DC load.

In one embodiment, the bidirectional converter may convert the first direct current voltage into the second direct current voltage and supply the second direct current voltage stored in the battery to the battery, And supplies the DC link capacitor to the DC link capacitor.

In the embodiment, the control unit compares the generated power and the amount of power of the direct current load, and determines whether to output the second direct current voltage stored in the battery according to the comparison result.

In the embodiment, if the power amount of the generated power is smaller than the power amount of the DC load as a result of the comparison, the controller converts the second DC voltage stored in the battery into the first DC voltage and supplies the converted DC voltage to the DC power supply And a control unit.

In the embodiment, if the power amount of the generated power is larger than the power amount of the DC load as a result of the comparison, the control unit converts the generated power into a first direct voltage and supplies the converted first direct voltage to the direct power supply, DC voltage to be supplied to the battery.

In an embodiment, the power supply apparatus according to the present invention further includes at least one relay provided between the direct current power supply and the direct current load.

In an embodiment, the relay performs an on-off operation of the provided relay switch based on a control command received from the control unit.

The power conversion unit may further include a DC link capacitor provided at an output terminal of the MPPT converter and at an input terminal of the DC power supply unit to smooth the first DC voltage.

A control method of a power supply apparatus according to an embodiment of the present invention is a control method of a power supply apparatus that supplies power to a DC load in association with a solar photovoltaic power generation apparatus, 1 < / RTI >voltage; A second step of determining whether to output a second direct current voltage stored in the battery and converting the output second direct current voltage into a first direct current voltage according to the generated power and the amount of electric power of the direct current load; A third step of rectifying the first DC voltage; And a fourth step of supplying the first DC voltage to the DC load according to a control command.

In one embodiment of the present invention, the first step and the second step may include smoothing the first DC voltage and supplying the smoothed first DC voltage to the DC power supply unit.

In the embodiment, the second step is a step of outputting a second DC voltage stored in the battery and converting the second DC voltage into the first DC voltage when the amount of electric power of the generated electric power is smaller than the electric power of the DC load .

In the embodiment, the second step is to stop the output of the second direct current voltage stored in the battery when the amount of electric power of the generated electric power is equal to or more than the electric power amount of the direct current load, And converting the second direct current voltage into a second direct current voltage and supplying the second direct current voltage to the battery.

Embodiments of the present invention provide a power supply apparatus that is connected to a photovoltaic power generation apparatus and supplies electric power to a load, directly supplies the generated generated power to the load, stores the generated generated power in a battery, DC conversion is performed without converting the AC voltage in the case of supplying the AC power, the system implementation is simple and the product cost is reduced due to the reduction of the parts.

Further, in the embodiments of the present invention, in the case of supplying the generated power output from the solar power generator to the load, the output power and / or the energy stored in the battery are directly supplied to the load, The battery in which the energy is stored can be used as the electroless power source device and the power stored in the battery can be more stably used due to the reduction of the conversion efficiency.

1 is a block diagram showing a schematic configuration of a system including a power supply apparatus according to an embodiment of the present invention;
2 is a schematic circuit configuration diagram of a power supply apparatus according to an embodiment of the present invention;
3 is a more detailed circuit diagram of the power supply apparatus according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a power supply apparatus and a method of controlling the same according to the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, a power supply apparatus 200 according to the present invention is connected to a photovoltaic power generation apparatus 100 to receive generated power, and converts the generated power voltage into a voltage suitable for the DC load 300 And supplies the DC load 300 to the DC load 300. 1, the power supply 200, the photovoltaic power generation apparatus 100, and the DC load 300 may be implemented as a single system, A power conversion unit 210, a control unit 230, and a battery 250.

The photovoltaic device 100 generates electric energy using sunlight and outputs the generated electric power to the power supply device 200.

The DC load 300 consumes generated power output from the photovoltaic device 100 and / or energy stored in the battery 250. That is, the direct current load 300 has a unidirectionality as a kind of consumer who receives power. The present invention will be described with reference to a household load (not limited to this) using a DC voltage.

In the embodiment of the present invention, the power conversion section 210 converts the generated power output from the photovoltaic device 100 into a first direct-current voltage and outputs the generated direct- The second DC voltage stored in the battery 250 is converted to the first DC voltage, and the first DC voltage is rectified and supplied to the DC load 300. Also, And the control unit 230 controls the operations of the power conversion unit 210. [

Referring to Figures 2 and 3, a circuit diagram of the power supply 200 is shown. The power supply 200 includes a power conversion unit 210 including an MPPT converter 211, a bidirectional DC converter 212, a DC link capacitor 213, and a DC power supply unit 215, A control unit 230, and a battery 250. Here, at least one relay 270 for connecting or disconnecting a current flow may be provided between the DC power supply unit 215 and the DC load 300.

The MPPT converter 211 boosts the power generated from the photovoltaic device 100 and outputs a first DC voltage. That is, the MPPT converter 211 functions as a boost DC-DC converter that boosts a DC voltage output from the solar cell generator 100 to a DC voltage within a predetermined range to output a first DC voltage. At this time, the first DC voltage may be, for example, 380V.

The MPPT converter 211 may be implemented as a unidirectional DC-DC converter including at least one IGBT switching element S1, a diode element, and a reactor L _pv , for example, as shown in Fig. 3 . The MPPT converter 211 controls MPPT (Maximum Power Point Tracking) of generated power output from the photovoltaic apparatus 100 according to a control command of the controller 230. Here, the MPPT control means that the value of the varying direct-current voltage is controlled so as to follow a specific reference value according to the characteristics of the solar cell generator 100 highly dependent on the solar radiation amount. For this purpose, An algorithm for following the maximum power point of the photovoltaic device 100 can be incorporated. This MPPT control may be performed, for example, by operating the IGBT switching device S1 provided in the MPPT converter 211 in accordance with the driving of the controller 230 in FIG.

The bidirectional DC converter 212 converts the first DC voltage into a second DC voltage suitable for the battery 250 in accordance with driving of the controller 230. Here, the first DC voltage may be, for example, 380 V and the second DC voltage may be 120V. The bidirectional DC converter 212 converts the second DC voltage stored in the battery 250 into the first DC voltage. For this purpose, the bi-directional DC converter 212 may include at least one IGBT switching device S2. The bidirectional DC converter 212 converts the first DC voltage into the second DC voltage and supplies the second DC voltage to the battery 250 or the second DC voltage stored in the battery 250, To the first DC voltage and supplies the DC voltage to the DC link capacitor 213. For example, it is assumed that the first DC voltage is 380V and the second DC voltage is 120V. In this case, when a control command for charging the battery 250 is received from the controller 230, the bidirectional DC converter 212 converts the DC voltage of 380 V to a DC voltage of 120 V and supplies the DC voltage to the battery 250. The bidirectional DC converter 212 converts a direct current voltage of 120V outputted from the battery 250 into a direct current voltage of 380V when a control command for discharging the battery 250 is received from the controller 230, For example, the DC link capacitor 213. [

The DC link capacitor 213 smoothes the input voltage and stores it as a DC link voltage. Specifically, the DC link capacitor 213 is provided at the output terminal of the MPPT converter 211 and at the input terminal of the DC power supply unit 215 to smooth the input first DC voltage. That is, the DC link capacitor 213 receives and smoothes the DC voltage output from the MPPT converter 211 or from the battery 250 via the bidirectional DC converter 212, and stores the DC voltage as a DC link voltage level .

The DC power supply unit 215 is provided at an input terminal of the DC load 300 to rectify the first DC voltage output from the MPPT converter 211 and / or the bidirectional DC converter 212. The DC power supply unit 215 may be a unidirectional DC-DC inverter having a pair of IGBT switching elements S4 and S5, and may further include a power factor improving circuit. Also, the DC power supply unit 215 supplies the rectified first DC voltage to the DC load 300 according to a control command.

The controller 230 controls overall operations of the power supply according to the present invention. The control unit 230 controls the DC power supply unit 215 to supply the rectified voltage to the DC load 300. The control unit 230 compares the power amount of the generated power output from the photovoltaic device 100 with the power amount of the direct current load 300 and compares the amount of the second direct current voltage stored in the battery 250 And determines whether or not to output it. The control unit 230 controls the MPPT control of the MPPT converter 211 or controls the flow of voltage and current of the bidirectional DC converter 212 by charging / discharging the battery 260, And controls and drives power factor correction (PFC) of the DC power supply unit 215.

As a result of the comparison by the controller 230, if the power amount of the generated power output from the photovoltaic device 100 is smaller than the power amount of the direct current load 300, the second direct voltage stored in the battery 250 is converted into the first direct voltage And supplies the first direct current voltage to the direct current power supply unit 215. On the other hand, as a result of the comparison by the controller 230, when the power amount of the generated power output from the solar cell generator 100 is equal to or greater than the power amount of the direct current load 300, the generated power is converted into the first direct voltage, Supply unit 215, and the surplus power is converted into a second direct-current voltage and supplied to the battery 250.

The relay 270 is provided between the DC power supply unit 215 and the DC load 300. The relay 270 opens and closes a current and a voltage supplied to the DC load 300 by performing an on-off operation of a relay switch provided on the basis of a control command received from the controller 230. More specifically, in order to supply power from the DC power supply unit 215 to the DC load 300, a switching element, for example, an IGBT included in the relay 270 is turned on, and a power supply to the DC load 300 And turns off the IGBT to cut off the supply. The operation of the switching element is based on a control command received from the control unit 230. [

The battery 250 stores generated electric power that is supplied to the DC load 300. Although not shown, the battery 250 may be implemented by connecting a plurality of battery cells in series or in parallel. The battery 250 may include a battery reactor L _batt and at least one IGBT switching device for externally outputting energy stored in the battery. The battery 250 may further include a battery management system (BMS) that performs charging / discharging operations of the battery based on a control command received from the controller 230.

In the case where the battery control device (BMS) is provided as described above, the second DC voltage stored in the battery 250 is discharged to the bidirectional DC converter 212 based on the control command received from the controller 250, The operation of charging the battery 250 with the second DC voltage converted by the bidirectional DC converter 212 is controlled by the battery control device (BMS). As shown in FIG. 3, the battery 250 and the battery control unit (BMS) may be integrally configured to take the form of a battery pack. The battery control unit (BMS) is connected to the battery 250 to maintain and manage the state of the battery.

In this manner, when the generated power output from the photovoltaic device 100 is supplied to the load 300, in particular, the direct current load, the generated power and / or the battery 250 Can be directly supplied to the DC voltage.

An exemplary control method of the power supply apparatus according to the embodiment of the present invention described above will be described as follows.

First, the generated power output from the associated photovoltaic device is converted into a first DC voltage (first process). At this time, the first DC voltage is, for example, boosted the voltage of generated power by using a DC converter. Then, it is determined whether to output the second direct current voltage stored in the battery, based on the generated power output from the solar power generation device and the amount of power of the direct current load. In accordance with the determination, the second DC voltage output from the battery is converted into a first DC voltage (step 2).

For example, if the amount of power output from the photovoltaic power generation apparatus is larger than the amount of power of the direct current load, the power required for the direct current load is supplied and the remaining power is charged in the battery. In this case, it is not necessary to output the second DC voltage stored in the battery. On the other hand, if the amount of power output from the photovoltaic power generation device is smaller than the amount of power of the direct current load, it is necessary to replenish the amount of power from the battery. That is, at this time, the second direct current voltage stored in the battery is controlled to be outputted, and the second direct current voltage outputted from the battery is converted into the second direct current voltage. Then, the power supply device rectifies the first DC voltage output to the first process and / or the second process (third process). Then, the rectified first DC voltage is supplied to the DC load in accordance with the control command of the control unit (fourth process).

On the other hand, when the sum of the generated power output from the photovoltaic power generator and the energy stored in the battery does not satisfy the power demand of the load, the load must be able to receive the necessary power from the power supply. To this end, the power supply unit and the power supply apparatus 200 according to the present invention can be implemented so as to be able to communicate with each other, thereby flexibly managing and processing the remaining power and the insufficient power. As an example, the power supply 200 may include a communication unit (not shown) to communicate with the power supply. The communication unit may include a communication method such as a wired / wireless communication method, a satellite communication method, .

As described above, in the control method of the power supply apparatus according to the present invention, in the case of directly supplying the generated power output from the solar power generation apparatus to the load, storing it in the battery, or supplying the energy stored in the battery to the load By controlling the DC-DC conversion to be performed only without converting the AC-DC or DC-AC, the system can be implemented easily and the product cost due to the reduction of the parts can be reduced.

Here, the first and second processes may further include smoothing the first DC voltage and supplying the smoothed first DC voltage to the DC power supply. To this end, at least one DC link capacitor may be provided at an input terminal of the DC power supply unit, and the DC link capacitor may store and maintain the smoothed DC voltage at a predetermined level. The power supply apparatus associated with the photovoltaic power generation apparatus does not store power to the DC link capacitor at the initial start-up. When the power supply apparatus according to the present invention is started according to the power supply request of the DC load, the generated power output from the solar power generation apparatus is supplied to the DC link capacitor and stored. At this time, if the generated power is insufficient to satisfy the required amount of power of the DC load, the energy stored in the battery is outputted to the DC link capacitor.

In the embodiment, if the power amount of the generated power output from the photovoltaic device is smaller than the power amount of the direct current load, the second direct current voltage stored in the battery is output and converted to the first direct current voltage. On the other hand, when the power amount of the generated power is equal to or more than the power amount of the DC load, the output of the second DC voltage stored in the battery is stopped, and the generated power exceeding the amount of power of the DC load is converted into the second DC voltage And then supplying the battery to the battery. That is, if the amount of generated power output from the photovoltaic power generation device is sufficient to supply power to the load, the direct current voltage is directly supplied to the load, and the amount of generated power is insufficient to supply power to all the loads , The energy stored in the battery is outputted to the load. As such, the battery is used as an uninterruptible power supply when no power is supplied from the system. To this end, an excess of the generated power output from the photovoltaic apparatus is stored in the battery, not in the system. Thus, the direct-current voltage of the generated power can be directly supplied to the load without performing the conversion of the AC-DC or the DC-AC.

As described above, the PV power supply apparatus and the control method thereof according to the embodiments of the present invention can be applied to a PV power supply apparatus and a control method thereof, In the case of supplying directly to a load, storing it in a battery, or supplying energy stored in a battery to a load, only a DC-DC conversion is performed without converting an AC voltage, thereby simplifying system implementation, Reduces costs. In addition, since the output of the generated power and / or the energy stored in the battery is directly supplied to the load, not the system, the battery storing the energy when the power failure occurs can be used as the electroless- The stored power can be used more stably.

100 - Photovoltaic device 200 - Power supply device
210 - Power conversion unit 211 - MPPT converter
212 - Bi-directional DC converter 213 - DC link capacitor
215 - DC power supply 230 -
250 - Battery 270 - Relay part
300 - DC load

Claims (14)

A power supply apparatus for supplying power to a DC load in association with a solar power generation apparatus,
A rectifier for rectifying the converted first DC voltage in accordance with the amount of power generated by the generated power and the DC load to supply the rectified DC voltage to the DC load, A power converting unit for converting a first DC voltage into a second DC voltage, rectifying the second DC voltage, and supplying the second DC voltage to the DC load;
A battery for storing the second DC voltage; And
And a control unit for controlling operation of the power conversion unit,
Wherein the power conversion unit comprises:
An MPPT converter for stepping up power generated from the photovoltaic device and outputting a first DC voltage;
A DC link capacitor provided between an output terminal of the MPPT converter and an input terminal of a DC power supply unit for smoothing the first DC voltage;
The control unit converts the first DC voltage into a second DC voltage suitable for the battery and provides the second DC voltage to the battery or converts the second DC voltage stored in the battery into the first DC voltage, A bidirectional converter for providing the output voltage to the inverter; And
And a DC power supply unit that is provided at an input terminal of the DC load and rectifies the first DC voltage stored in the DC link capacitor and is outputted from at least one of the MPPT converter and the bidirectional converter and supplies the rectified first DC voltage to the DC load,
Wherein,
Comparing the power generation amount of the generated power and the DC load,
If the power of the generated power is smaller than the amount of power of the DC load, the second DC voltage stored in the battery is converted into the first DC voltage through the bidirectional converter and then supplied to the DC power supply through the DC link capacitor Respectively,
And controls the DC power supply unit to supply the first DC voltage output from the MPPT converter to the DC power supply unit through the DC link capacitor when the power amount of the generated power is equal to or greater than the power amount of the DC load. delete delete delete delete delete The method according to claim 1,
Wherein,
Wherein the control unit converts the generated power into a first direct current voltage and provides the direct current power to the direct current power supply unit when the power amount of the generated electric power is equal to or greater than the electric power amount of the direct current load, Power supply to the power supply unit. The method according to claim 1,
And at least one relay provided between the DC power supply and the DC load. 9. The method of claim 8,
The relay includes:
And performs an on-off operation of the provided relay switch based on a control command received from the control unit. delete A control method of a power supply apparatus that supplies power to a DC load in association with a solar power generation apparatus,
A first step of boosting the generated power output from the photovoltaic device through an MPPT converter and converting the generated power into a first DC voltage;
A second step of comparing the generated power and the amount of power of the DC load;
If the power amount of the generated power is smaller than the power amount of the DC load, the second DC voltage stored in the battery is converted into the first DC voltage through the bidirectional converter, and then supplied to the DC power supply through the DC link capacitor,
A third step of providing a first DC voltage output from the MPPT converter to the DC power supply through the DC link capacitor when a power amount of the generated power is equal to or greater than a power amount of the DC load;
And a fourth step of rectifying the first DC voltage of the DC power supply unit and supplying the rectified DC voltage to the DC load. delete delete delete

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