KR102367016B1 - inverter - Google Patents

Abstract

The present invention relates to an inverter,
Through a diode at the output terminal of the solar module, it is connected in parallel to the sources of two field effect transistors, which are switching means,
A capacitor and a diode are connected in parallel with the drain-source of the field effect transistor so that the boosted AC power is output while passing through the field effect transistor,
A square wave is alternately supplied with a cycle of 60 Hz from the driver to the gates of each of the two field effect transistors, which are the switching means, and turned on;
At the drains of the two field effect transistors, which are the switching means, which are alternately turned on at a cycle of 60 Hz, the converted AC power is applied to both ends of the primary side where the middle tap of the transformer is grounded,
The converted AC power output from the drains of two field effect transistors, which are a plurality of switching means, is applied to each of the plurality of primary sides of the transformer arranged in series. It is constructed so that it can be obtained with high efficiency.

Description

inverter {inverter}

The present invention relates to an inverter of a generator for an electric vehicle as well as wind power, hydropower, and solar power generation, and in detail, by combining two switching means each having a step-up circuit in one photovoltaic module, alternately at a cycle of 60 Hz It relates to an inverter in which the boosted AC power can be obtained with high efficiency while being stabilized by a simple configuration by turning it on and allowing the boosted AC power from a plurality of solar modules to be applied to the primary side of the transformer through a resonance circuit.

In general, it is a well-known fact that research on new and renewable energies such as solar and wind power, which are representative environmentally friendly green energies, is being actively conducted as problems such as depletion of natural resources and environmental and stability issues for thermal and nuclear power generation have recently emerged. am.

Renewable energy such as solar power generation is in the spotlight from the point of view of infinite and clean energy, from large commercial power generation complexes to vehicles (trains), residential power generation and street lights, as well as unmanned lighthouses, clock towers, communication equipment and It is widely used in special equipment, etc.

For example, a photovoltaic power generation system is generally composed of a solar cell module, a storage battery, and an inverter, although it is different in the field of use of the system, the type of load, and location conditions.

If you want to use the method of transferring solar energy directly to the power source without a storage device such as a storage battery, a linked inverter is applied for this purpose. The inverter circuit, which is an interface circuit for connecting with the AC system, occupies an important part.

In addition to solar power generation, in the case of generating power by wind power or tidal power, the configuration of an inverter is essential for power supply of power converted from a storage battery that has stored the generated power.

Among the interface circuits, the current source inverter has the advantage that it is irrelevant even if the output voltage of the inverter is lower than the grid voltage when connecting to the grid, and there is no inrush current for a short circuit in the case of a load short circuit or an inverter accident.

When applying such a current source inverter to a photovoltaic power generation system, a controller using a processor is generally used. In order to reduce the size of the inductance and the ripple of the output current, it must be controlled at a high switching frequency. And there is a problem in that the case is limited by the sampling frequency according to the performance of the processor.

Thus, on March 17, 2003, Patent Application No. 10-2003-0016570 (current source inverter by parallel switching) was proposed,

This relates to a current source inverter by parallel switching for realizing low distortion and high efficiency by configuring the converter in parallel as a linkage inverter device,

They are connected in parallel to each other so that when the switch of one converter is turned off/on, the other converter is driven by a parallel buck-boost converter that turns on/off. The resulting output voltage ripple is also greatly reduced, so that the efficiency characteristics are improved.

And the inverters of the full-bridge circuit implement a single-phase or three-phase bridge circuit to supply power to the wiring network. was located.

Also, the switches of the bridge circuit can be connected symmetrically or asymmetrically.

In order to isolate this configuration from the DC side, DE 10 2004 030 912 B3 proposes to connect the 5th switch between the positive pole of the DC power supply and the two bridge branches.

This fifth switch is connected at high frequency and simultaneously connected to the two lower switches of the bridge branch, but each upper switch of the bridge branch is closed for half a wave of the network voltage so that the switches are clocked asymmetrically. did.

In the full-bridge circuit introduced in WO2008015298A1, a divided intermediate circuit is installed at the input terminal so that a switch is connected in series between the intermediate circuit and each DC line between the bridge and the bridge. These switches alternately clock at the same high frequency with each of the two subswitches of the bridge branch, but during each half-wave of the network voltage, each of the upper switches of the bridge branch are closed.

The freewheel path is further constituted by two series diodes connected upstream of the bridge branch, and the center tap of the intermediate circuit is connected to the center tap.

A three-stage circuit configuration is also known. In this circuit configuration, the bridge branch consists of four switches, of which two central switches are bridged by two series-connected diodes during the freewheeling time, so that the voltage load of the operating switch is reduced.

Also, on June 15, 2009, Patent Application No. 10-2009-0052647 (inverter) was proposed,

In the inverter for supplying the power of the DC power supply to the AC voltage wiring network (N):

an asymmetric switching bridge circuit having only four switches;

Two first switches of the four switches switch at the same frequency as the wiring network and form a part of the first element assembly, and the remaining two second switches switch at a frequency higher than the frequency of the wiring network and are separated from the first element assembly form part of a spatially separated second component assembly;

The second switch has a steeper switching slope and higher temperature stability than the first low-speed switch,

a first cooling element is connected to the first element assembly and a second cooling element different from the first cooling element is connected to a second element assembly;

The second cooling element was configured to be larger in size than the first cooling element.

However, according to the conventional inverter as described above, an electrolytic capacitor must be provided, and the lifespan of this capacitor is significantly lower than that of a general semiconductor, and the lifespan of the entire inverter is shortened depending on the characteristics of the surrounding environment. There was a problem with the deterioration.

Thus, the present applicant's published Patent Publication No. 10-2014-0044428 dated April 15, 2014 (inverter for power generation omitting a capacitor) has been proposed,

This allows DC power from a generator or storage battery such as solar, wind, and tidal power to be applied to the primary side of the first transformer, where the external AC power and the secondary are connected,

Two switching elements are installed on both sides of the intermediate tap of the primary side of the first transformer,

Two gate driving ICs are respectively connected to both sides of the middle tap of the secondary side of the second transformer where the primary side is connected to the external AC power source,

A switching IC is installed on the wire to which AC power induced from the secondary side of the first transformer is supplied, and AC power of the same frequency having the same firing angle as the AC power is connected while being alternately turned on by the two gate driving ICs The power factor is improved by fast switching while having the same firing angle by supplying it to the supplied wire, and the lifespan of the inverter is remarkably long by omitting the capacitor tank group including the electrolytic capacitor in a simple configuration.

However, the conventional inverter for power generation in which the condenser is omitted as described above has a disadvantage in that the DC power from the solar module is directly converted into AC power and the configuration is complicated, and the efficiency decreases while passing through a number of components.

Accordingly, the present invention is to solve the conventional problems as described above, by combining two switching means each having a step-up circuit in one photovoltaic module so as to be turned on alternately at a cycle of 60Hz, and a plurality of photovoltaic modules Applied to electric vehicle generators as well as wind power, hydropower, and solar power generation that allows the boosted AC power to be applied to the primary side of the transformer through a resonance circuit and is stabilized by a simple configuration to obtain the boosted AC power with high efficiency It aims to provide a possible inverter.

The inverter of the present invention for achieving the above object,

It is connected in parallel to the source of two field effect transistors, which are switching means, through a diode at the output terminal of the solar module,

A capacitor and a diode are connected in parallel with the drain-source of the field effect transistor so that the boosted AC power is output while passing through the field effect transistor,

A square wave from the driver is alternately supplied to the gates of the two field effect transistors as the switching means at a cycle of 60 Hz and turned on;

At the drains of the two field effect transistors, which are the switching means, which are alternately turned on at a cycle of 60 Hz, the converted AC power is applied through the capacitor forming a resonance circuit with the transformer at both ends of the primary side where the intermediate tap of the transformer is grounded, ,

AC power is applied from the drains of two field effect transistors, which are a plurality of switching means, to each of the primary sides of the transformers arranged in series, so that the secondary side of the transformer is stabilized and boosted AC power is obtained with high efficiency. will be.

According to the inverter according to the present invention, the output terminal of the photovoltaic module is connected in parallel to the sources of two field effect transistors, which are switching means, and a capacitor and a diode are connected in parallel with the drain-source of the field effect transistor. Thus, the boosted DC power is output while passing through the field effect transistor, and the boosted AC power is supplied to the drains of the two field effect transistors, which are alternately turned on by the square wave supplied alternately at a cycle of 60 Hz supplied from the driver. to be created

Stabilization on the secondary side of the transformer by allowing the AC power to be applied from the drains of each of the two field effect transistors, which are a plurality of switching means, to the primary sides of the transformers arranged in series through the inductance of the transformer and the capacitor forming the resonance circuit. This has the effect of obtaining the boosted AC power with high efficiency.

1 is a schematic diagram showing the overall configuration of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

The inverter according to the present invention is intended to be used for wind power, hydro power, solar power generation as well as for electric vehicle generators,

A photovoltaic module (1)...(1n) that converts light energy into electric energy by sunlight; and

Switching means (2) ... (2n) coupled in parallel to the output terminal of the solar module (1)...

A first diode (D111, D121)...(D11n, D12n) and capacitors (C11, C21)...(C1n, C2n) and a second diode (D11n, D12n) connected in parallel to the switching means (2)...(2n) Step-up means (3)...(3n) consisting of 2 diodes (D211, D221)...(D21n, D22n);

a driver (4) for selectively turning on while alternately supplying a 60Hz cycle square wave to the switching means (2)...(2n);

The primary side (T11)...( T1n) is applied through the capacitors C31 and C41 (C3n, C4n) of the resonance circuit, respectively, and the transformer 5 is configured to obtain the desired AC power from the secondary side T2.

That is, the switching means (2)...(2n) of two field effect transistors (F11, F21)...(F1n, F2n) at the output terminal of the solar module (1)...(1n) The first diodes (D111, D121), (D11n, D12n) of the step-up means (3) ... (3n) are respectively connected in parallel to the source (S),

To the gates G of the two field effect transistors F11, F21... and,

The step-up means (3) ... (3n) between the output terminal of the solar module and the field effect transistors (F11, F21)... (F1n, F2n) of the switching means (2)... (2n) 1 While connecting diodes D111, D121, (D11n, D12n), capacitors C11 and C21 in parallel with the drain-source of the field effect transistors F11, F21 ... (F1n, F2n). .(C1n, C2n) and the second diode (D211, D221)...(D21n, D22n) are connected,

At the drains D of the two field effect transistors F11, F21 ... (F1n, F2n), which are the switching means 2 ... A plurality of primary side (T11) of the transformer (5) ... (T11) at both ends of the primary side (T11) ... (T1n) of which the intermediate tap (t1) ... (tn) of this transformer (5) is grounded, respectively. (T1n) and the capacitors (C31, C41) ... (C3n, C4n) forming the resonance circuit,

AC power converted by a square wave output from the drains of two field effect transistors (F11, F21)...(F1n, F2n) as a plurality of switching means (2)...(2n) is arranged in series Capacitors C31, C41...(C3n, C4n) each forming a resonance circuit in the middle taps t1...(tn) of a plurality of primary sides T11...(T1n) of one transformer 5 ) to be applied through the stabilized secondary side (T2) of the transformer (5) and is configured to obtain the boosted AC power with high efficiency.

The inverter of the present invention configured as described above,

Sources of two field effect transistors (F11, F12) ... (F1n, F2n) that are switching means (2)... S) connected in parallel.

A square wave from the driver 4 alternates at a cycle of 60 Hz at the gates G of the two field effect transistors F11, F21... (F1n, F2n) that are the switching means 2... Make it warm as it is supplied with

In the drain (D) of the two field effect transistors (F11, F21)...(F1n, F2n), which are the switching means (2)...(2n), which are turned on alternately with a cycle of 60Hz, the solar module ( 1) At the output terminal of ...(1n), the AC power converted from DC power is output.

At this time, between the output terminal of the solar module and the field effect transistors F11, F21 ... (F1n, F2n) of the switching means 2 ... While connecting the first diodes D111, D121, (D11n, D12n) of Since ... (C1n, C2n) and the second diodes (D211, D221) ... (D21n, D22n) are connected, the output AC power is boosted to increase the power generation efficiency.

The boosted AC power supply is connected to both ends of the primary side (T11)...(T1n) to which the intermediate tap (t1)...(tn) of the transformer (5) is grounded in a plurality of primary sides (T11) ). A plurality of primary sides (T11) ... (T1n) of the transformer (5) in which the AC power converted by the square wave output from the drains of the effect transistors (F11, F21)...(F1n, F2n) is arranged in series ), so that the boosted AC power is obtained with high efficiency while being stabilized at the secondary side (T2) of the transformer (5).

In the above, a preferred embodiment of the present invention has been illustrated and described, but the present invention is not limited to the above-described embodiment, and it is common in the field to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Any person skilled in the art can implement various modifications, and such modifications are within the scope of the described claims.

1...1n: solar module 2...2n: switching means
3...3n: boosting means 4: driver
5: Transformers

Claims (1)

A photovoltaic module (1) for generating electricity that converts sunlight into electrical energy,
A switching means (2) that is coupled in parallel to the output terminal of the solar module (1) and converts DC power into AC power by an alternately on state;
a driver (4) for selectively turning on while alternately supplying a square wave of a 60 Hz cycle to the switching means (2);
AC power is obtained from the secondary side (T2) while the AC power converted and output from the switching means (2), which is turned on alternately at a cycle of 60Hz, is applied to both ends of the primary side (T11) with the intermediate tap (t1) grounded It consists of a transformer (5)
The step-up means (3) ... (3n) between the output terminal of the photovoltaic module and the field effect transistors (F11, F21) ... (F1n, F2n) of the switching means (2) ... (2n) 1 While connecting diodes D111, D121, (D11n, D12n), capacitors C11 and C21 in parallel with the drain-source of the field effect transistors F11, F21 ... (F1n, F2n). . (C1n, C2n) and the second diode (D211, D221) ... (D21n, D22n) to be connected,
AC power converted by a square wave output from the drains of two field effect transistors (F11, F21)...(F1n, F2n) as a plurality of switching means (2)...(2n) is arranged in series AC power stably boosted by being applied through a plurality of primary sides (T11)...(T1n) of the transformer 5 and capacitors (C31, C41)...(C3n, C4n) forming a resonance circuit Inverter, characterized in that configured to obtain.

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