CN214506898U - Transformer integrated multi-level battery energy storage power converter - Google Patents

Abstract

The utility model belongs to the electrical automation equipment field especially relates to a many level battery energy storage power deflector of transformer integration. The three-phase direct current power supply system comprises a three-winding transformer, six single-phase voltage source inverter bridges, a six-phase alternating current reactor, six filter capacitors, two three-phase energy-taking transformers, two three-phase rectifier bridges and two direct current filter reactors. The phase voltage output by the inverter bridge in the device is three-level, but a clamping diode of the NPC three-level inverter is omitted, so that the overall cost is lower, and the conversion efficiency is higher. The six-phase alternating current reactors can better realize the balance of the alternating current side currents of the two three-point voltage source inverter bridges, and can also be realized by adopting two three-phase alternating current reactors. The primary side and the secondary side of the three-winding transformer can be connected in a triangular connection or star connection mode, and the number of windings of the secondary side of the three-winding transformer can be increased so as to be connected with more inverters and filter circuits, so that the capacity of the device is expanded.

Description

Transformer integrated multi-level battery energy storage power converter

Technical Field

The utility model belongs to the electrical automation equipment field especially relates to a many level battery energy storage power deflector of transformer integration.

Background

For a battery energy storage device with a direct-current voltage of 1500V, a 1200V IGBT device and a neutral-point voltage clamp (NPC) three-level inverter are generally adopted for realizing the switching frequency of a power device of about 5 kHz. For a high-capacity (more than 1 MW) battery energy storage device, as a power grid of more than 10kV needs to be accessed, one half of the battery energy storage power conversion device is connected to the power grid through a transformer in a boosting mode. The NPC three-level inverter adopts the clamping diode or the clamping IGBT branch circuit to realize three-level phase voltage output, so that the cost and the loss of the inverter are increased. When the transformer is adopted to boost voltage and is connected to a power grid, the three-level phase voltage output of the inverter can be realized by utilizing the wiring mode of the transformer winding. Therefore, the transformer integrated multi-level battery energy storage power converter with lower cost and higher efficiency has important economic significance.

Disclosure of Invention

The utility model aims at providing a many level battery energy storage power conversion device of transformer integration to overcome prior art not enough, reduce power conversion device's cost and improve power conversion efficiency.

The utility model provides a many level of transformer integration battery energy storage power conversion equipment, including a three winding transformer T, first single-phase voltage source inverter bridge, second single-phase voltage source inverter bridge, third single-phase voltage source inverter bridge, fourth single-phase voltage source inverter bridge, fifth single-phase voltage source inverter bridge, sixth single-phase voltage source inverter bridge, a six-phase alternating current reactor L1, first filter capacitor CA1, second filter capacitor CB1, third filter capacitor CC1, fourth filter capacitor CA2, fifth filter capacitor CB2, sixth filter capacitor CC2, first three-phase can transformer T1, second three-phase can transformer T2, first three-phase rectifier bridge B1, second three-phase rectifier bridge B2, first direct current filter reactor L2 and second direct current filter L3;

the direct current positive ends of the first single-phase voltage source inverter bridge, the second single-phase voltage source inverter bridge and the third single-phase voltage source inverter bridge are connected in parallel, the direct current positive end of the first single-phase voltage source inverter bridge is connected to the direct current positive output end of the transformer integrated multi-level battery energy storage power converter, the direct current negative ends of the first single-phase voltage source inverter bridge, the second single-phase voltage source inverter bridge and the third single-phase voltage source inverter bridge are respectively connected in parallel, and the direct current negative end of the third single-phase voltage source inverter bridge is connected to the direct current positive end of the fourth single-phase voltage source inverter bridge; the direct current negative ends of the fourth single-phase voltage source inverter bridge, the fifth single-phase voltage source inverter bridge and the sixth single-phase voltage source inverter bridge are connected in parallel, and the direct current negative end of the sixth single-phase voltage source inverter bridge is connected to the direct current negative output end of the transformer integrated multi-level battery energy storage power converter;

first alternating current output ends of the first single-phase voltage source inverter bridge, the second single-phase voltage source inverter bridge and the third single-phase voltage source inverter bridge are respectively connected to a first group of three-phase cross current terminals on the input side of a six-phase alternating current reactor L1, first alternating current output ends of the fourth single-phase voltage source inverter bridge, the fifth single-phase voltage source inverter bridge and the sixth single-phase voltage source inverter bridge are respectively connected to a second group of three-phase cross current terminals on the input side of a six-phase alternating current reactor L1, a first group of three-phase alternating current terminals on the output side of the six-phase alternating current reactor L1 are respectively connected to one ends of a first filter capacitor CA1, a second filter capacitor CB1 and a third filter capacitor CC1, and a second group of three-phase alternating current terminals on the output side of a six-phase alternating current reactor L1 are respectively connected to one ends of a fourth filter capacitor CA2, a fifth filter capacitor CB2 and a sixth filter capacitor CC 2;

second alternating current output ends of the first single-phase voltage source inverter bridge, the second single-phase voltage source inverter bridge and the third single-phase voltage source inverter bridge are respectively connected to the other ends of the first filter capacitor CA1, the second filter capacitor CB1 and the third filter capacitor CC1, and second alternating current output ends of the fourth single-phase voltage source inverter bridge, the fifth single-phase voltage source inverter bridge and the sixth single-phase voltage source inverter bridge are respectively connected to the other ends of the fourth filter capacitor CA2, the fifth filter capacitor CB2 and the sixth filter capacitor CC 2; two ends of a first filter capacitor CA1, a second filter capacitor CB1 and a third filter capacitor CC1 are respectively connected to six leading-out ends of a first secondary side three-phase winding of a three-winding transformer T, two ends of a fourth filter capacitor CA2, a fifth filter capacitor CB2 and a sixth filter capacitor CC2 are respectively connected to six leading-out ends of a second secondary side three-phase winding of the three-winding transformer T, and a primary side three-phase winding leading-out end of the three-winding transformer T is connected to a power grid;

six leading-out ends of a primary side three-phase winding of the first three-phase energy-taking transformer T1 are respectively connected to first and second alternating current output ends of a first single-phase voltage source inverter bridge, a second single-phase voltage source inverter bridge and a third single-phase voltage source inverter bridge, a secondary side three-phase alternating current end of the first three-phase energy-taking transformer T1 is respectively connected to three alternating current ends of a first three-phase rectifier bridge B1, a direct current positive end of the first three-phase rectifier bridge B1 is connected to a direct current positive end of a fourth single-phase voltage source inverter bridge, a direct current negative end of the first three-phase rectifier bridge B1 is connected to one end of a first direct current filter reactor L2, and the other end of the first direct current filter reactor L2 is connected to a direct current negative end of a sixth single-phase voltage source bridge;

six leading-out ends of a primary side three-phase winding of the second three-phase energy-taking transformer T2 are respectively connected to first and second alternating-current output ends of a fourth single-phase voltage source inverter bridge, a fifth single-phase voltage source inverter bridge and a sixth single-phase voltage source inverter bridge, a secondary side three-phase alternating-current end of the second three-phase energy-taking transformer T2 is respectively connected to three alternating-current ends of a second three-phase rectifier bridge B2, a direct-current positive end of the second three-phase rectifier bridge B2 is connected to one end of a second direct-current filter reactor L3, the other end of the second direct-current filter reactor L3 is connected to a direct-current positive end of the first single-phase voltage source inverter bridge, and a direct-current negative end of the second three-phase rectifier bridge B2 is connected to a direct-current negative end of the third single-phase voltage source inverter bridge.

The utility model provides a many level battery energy storage power deflector of transformer integration, its advantage:

compare with existing power conversion device parallelly connected based on three-phase two-level or NPC three-level dc-to-ac converter commonly used, the utility model discloses a many level battery energy storage power conversion device of transformer integration, wherein the looks voltage of inverter bridge output also is three-level, has nevertheless saved the clamp diode of NPC three-level dc-to-ac converter, makes the utility model discloses a battery energy storage power conversion device's overall cost is lower, and conversion efficiency is higher. The six-phase alternating current reactor can better realize the balance of the alternating current side currents of the two three-point voltage source inverter bridges, and the six-phase alternating current reactor can also be realized by adopting two three-phase alternating current reactors. The primary side and the secondary side of the three-winding transformer can be connected in a triangular connection or star connection mode, and the number of windings of the secondary side of the three-winding transformer can be increased so as to be connected with more inverters and filter circuits, so that the capacity of the device is expanded.

Drawings

Fig. 1 is a schematic circuit diagram of the transformer integrated multilevel battery energy storage power converter device provided by the utility model.

Fig. 2 is a schematic circuit diagram of a single-phase voltage source inverter bridge in the transformer integrated multilevel battery energy storage power converter of the present invention.

Detailed Description

The utility model provides a many level battery energy storage power conversion equipment of transformer integration, its schematic circuit diagram is shown in fig. 1, including a three winding transformer T, first single-phase voltage source inverter bridge, the single-phase voltage source inverter bridge of second, the single-phase voltage source inverter bridge of third, the single-phase voltage source inverter bridge of fourth, the single-phase voltage source inverter bridge of fifth, the single-phase voltage source inverter bridge of sixth, a six-phase alternating current reactor L1, first filter capacitor CA1, second filter capacitor CB1, third filter capacitor CC1, fourth filter capacitor CA2, fifth filter capacitor CB2, sixth filter capacitor CC2, first three-phase reactor T1, second three-phase energy-taking transformer T2, first three-phase rectifier bridge B1, second three-phase rectifier bridge B2, first direct current filter L2 and second direct current filter reactor L3;

the direct current positive ends of the first single-phase voltage source inverter bridge, the second single-phase voltage source inverter bridge and the third single-phase voltage source inverter bridge are connected in parallel, the direct current positive end of the first single-phase voltage source inverter bridge is connected to the direct current positive output end of the transformer integrated multi-level battery energy storage power converter, the direct current negative ends of the first single-phase voltage source inverter bridge, the second single-phase voltage source inverter bridge and the third single-phase voltage source inverter bridge are respectively connected in parallel, and the direct current negative end of the third single-phase voltage source inverter bridge is connected to the direct current positive end of the fourth single-phase voltage source inverter bridge; the direct current negative ends of the fourth single-phase voltage source inverter bridge, the fifth single-phase voltage source inverter bridge and the sixth single-phase voltage source inverter bridge are connected in parallel, and the direct current negative end of the sixth single-phase voltage source inverter bridge is connected to the direct current negative output end of the transformer integrated multi-level battery energy storage power converter;

first alternating current output ends of the first single-phase voltage source inverter bridge, the second single-phase voltage source inverter bridge and the third single-phase voltage source inverter bridge are respectively connected to a first group of three-phase cross current terminals on the input side of a six-phase alternating current reactor L1, first alternating current output ends of the fourth single-phase voltage source inverter bridge, the fifth single-phase voltage source inverter bridge and the sixth single-phase voltage source inverter bridge are respectively connected to a second group of three-phase cross current terminals on the input side of a six-phase alternating current reactor L1, a first group of three-phase alternating current terminals on the output side of the six-phase alternating current reactor L1 are respectively connected to one ends of a first filter capacitor CA1, a second filter capacitor CB1 and a third filter capacitor CC1, and a second group of three-phase alternating current terminals on the output side of a six-phase alternating current reactor L1 are respectively connected to one ends of a fourth filter capacitor CA2, a fifth filter capacitor CB2 and a sixth filter capacitor CC 2;

second alternating current output ends of the first single-phase voltage source inverter bridge, the second single-phase voltage source inverter bridge and the third single-phase voltage source inverter bridge are respectively connected to the other ends of the first filter capacitor CA1, the second filter capacitor CB1 and the third filter capacitor CC1, and second alternating current output ends of the fourth single-phase voltage source inverter bridge, the fifth single-phase voltage source inverter bridge and the sixth single-phase voltage source inverter bridge are respectively connected to the other ends of the fourth filter capacitor CA2, the fifth filter capacitor CB2 and the sixth filter capacitor CC 2; two ends of a first filter capacitor CA1, a second filter capacitor CB1 and a third filter capacitor CC1 are respectively connected to six leading-out ends of a first secondary side three-phase winding of a three-winding transformer T, two ends of a fourth filter capacitor CA2, a fifth filter capacitor CB2 and a sixth filter capacitor CC2 are respectively connected to six leading-out ends of a second secondary side three-phase winding of the three-winding transformer T, and a primary side three-phase winding leading-out end of the three-winding transformer T is connected to a power grid;

six leading-out ends of a primary side three-phase winding of the first three-phase energy-taking transformer T1 are respectively connected to first and second alternating current output ends of a first single-phase voltage source inverter bridge, a second single-phase voltage source inverter bridge and a third single-phase voltage source inverter bridge, a secondary side three-phase alternating current end of the first three-phase energy-taking transformer T1 is respectively connected to three alternating current ends of a first three-phase rectifier bridge B1, a direct current positive end of the first three-phase rectifier bridge B1 is connected to a direct current positive end of a fourth single-phase voltage source inverter bridge, a direct current negative end of the first three-phase rectifier bridge B1 is connected to one end of a first direct current filter reactor L2, and the other end of the first direct current filter reactor L2 is connected to a direct current negative end of a sixth single-phase voltage source bridge;

six leading-out ends of a primary side three-phase winding of the second three-phase energy-taking transformer T2 are respectively connected to first and second alternating-current output ends of a fourth single-phase voltage source inverter bridge, a fifth single-phase voltage source inverter bridge and a sixth single-phase voltage source inverter bridge, a secondary side three-phase alternating-current end of the second three-phase energy-taking transformer T2 is respectively connected to three alternating-current ends of a second three-phase rectifier bridge B2, a direct-current positive end of the second three-phase rectifier bridge B2 is connected to one end of a second direct-current filter reactor L3, the other end of the second direct-current filter reactor L3 is connected to a direct-current positive end of the first single-phase voltage source inverter bridge, and a direct-current negative end of the second three-phase rectifier bridge B2 is connected to a direct-current negative end of the third single-phase voltage source inverter bridge.

The utility model provides a many level battery energy storage power conversion device of transformer integration can adopt conventional single-phase two level voltage source contravariant bridges, and its schematic circuit diagram is shown in figure 2, also can adopt conventional single-phase NPC three level voltage source contravariant bridges. In practical application, in order to enlarge the capacity of the power converter, the single-phase two-level voltage source inverter bridge or the single-phase NPC three-level voltage source inverter bridge can also operate in a mode that a plurality of direct current sides are directly connected in parallel with alternating current sides and connected in parallel through reactors.

The utility model discloses a many level battery energy storage power conversion device of transformer integration's theory of operation is: the positive end and the negative end of the energy storage battery pack are respectively connected to a direct current positive output positive end DC + and a direct current negative output end DC-of the transformer integrated multi-level battery energy storage power converter. The direct current sides of the first/second/third single-phase voltage source inverter bridge and the fourth/fifth/sixth single-phase voltage source inverter bridge form a series connection relation to adapt to higher direct current voltage of the energy storage battery, and the alternating current output ends are respectively connected to the secondary low-voltage winding of the three-winding transformer after being filtered by a filter consisting of L1 and CA1/CB1/CC1/CA2/CB2/CC2, so that isolation of the alternating current sides of the two groups of three single-phase voltage source inverter bridges is formed. When the power converter is in a charging operation mode, the first/second/third single-phase voltage source inverter bridge and the fourth/fifth/sixth single-phase voltage source inverter bridge are controlled by the power converter controller, so that active power flows from the source side to the secondary side of the three-winding transformer, is converted into direct current through the first/second/third single-phase voltage source inverter bridge and the fourth/fifth/sixth single-phase voltage source inverter bridge, and flows to two groups of energy storage batteries, and the batteries are charged; when the device is in a discharging operation mode, the first/second/third single-phase voltage source inverter bridge and the fourth/fifth/sixth single-phase voltage source inverter bridge are controlled by the power converter controller, so that active power flows from the two groups of energy storage batteries to the first/second/third single-phase voltage source inverter bridge and the fourth/fifth/sixth single-phase voltage source inverter bridge, is converted into alternating current, flows to the three-winding transformer and finally flows to an alternating current power supply on the source side of the three-winding transformer, and discharging of the batteries is achieved. In order to reduce harmonic current flowing to the transformer power grid side by the first/second/third single-phase voltage source inverter bridge and the fourth/fifth/sixth single-phase voltage source inverter bridge, the carrier phase shift mode can be adopted for PWM control pulses of the first/second/third single-phase voltage source inverter bridge and the fourth/fifth/sixth single-phase voltage source inverter bridge.

The direct-current voltages of the first/second/third single-phase voltage source inverter bridge and the fourth/fifth/sixth single-phase voltage source inverter bridge are respectively sampled by the power converter controller, and form feedback control to adjust the active power of the alternating-current side of each inverter bridge, so that the direct-current voltages of the two inverter bridges are kept balanced, and the safe operation of power devices of the inverter bridges is ensured. The energy-taking transformer T1/T2, the three-phase rectifier bridge B1/B2 and the direct-current filter reactor L2/L3 form a direct-current voltage balance auxiliary control circuit, and the principle is as follows: when the direct-current voltage of the first/second/third single-phase voltage source inverter bridge is higher, the amplitude of the output alternating-current voltage is also higher, the direct-current voltage is isolated by T1 and rectified by B1, and then the direct-current side of the fourth/fifth/sixth single-phase voltage source inverter bridge is charged through L2, so that the direct-current voltage of the fourth/fifth/sixth single-phase voltage source inverter bridge is increased until the direct-current voltage is as high as the direct-current voltage of the first/second/third single-phase voltage source inverter bridge, and then the charging is stopped, and therefore the balance control of the direct-current voltages of the two inverter bridges is realized.

The utility model discloses an among the many level battery energy storage power conversion device of transformer integration, six looks alternating current reactors can be better realize two three point voltage source contravariant bridge alternating current side current's equilibrium, six looks alternating current reactors also can adopt two three-phase alternating current reactors to realize. The primary side and the secondary side of the three-winding transformer can be connected in a triangular connection or star connection mode, and the number of windings of the secondary side of the three-winding transformer can be increased so as to be connected with more inverters and filter circuits, so that the capacity of the device is expanded.

Any is based on the utility model discloses the equivalent transformation circuit that the circuit was done all belongs to the utility model discloses a protection scope.

Claims (1)

1. A transformer integrated multi-level battery energy storage power converter is characterized by comprising a three-winding transformer T, a first single-phase voltage source inverter bridge, a second single-phase voltage source inverter bridge, a third single-phase voltage source inverter bridge, a fourth single-phase voltage source inverter bridge, a fifth single-phase voltage source inverter bridge, a sixth single-phase voltage source inverter bridge, a six-phase alternating current reactor L1, a first filter capacitor CA1, a second filter capacitor CB1, a third filter capacitor CC1, a fourth filter capacitor CA2, a fifth filter capacitor CB2, a sixth filter capacitor CC2, a first three-phase energy-taking transformer T1, a second three-phase energy-taking transformer T2, a first three-phase rectifier bridge B1, a second three-phase rectifier bridge B2, a first direct current filter reactor L2 and a second direct current filter transformer L3;

the direct current positive ends of the first single-phase voltage source inverter bridge, the second single-phase voltage source inverter bridge and the third single-phase voltage source inverter bridge are connected in parallel, the direct current positive end of the first single-phase voltage source inverter bridge is connected to the direct current positive output end of the transformer integrated multi-level battery energy storage power converter, the direct current negative ends of the first single-phase voltage source inverter bridge, the second single-phase voltage source inverter bridge and the third single-phase voltage source inverter bridge are respectively connected in parallel, and the direct current negative end of the third single-phase voltage source inverter bridge is connected to the direct current positive end of the fourth single-phase voltage source inverter bridge; the direct current negative ends of the fourth single-phase voltage source inverter bridge, the fifth single-phase voltage source inverter bridge and the sixth single-phase voltage source inverter bridge are connected in parallel, and the direct current negative end of the sixth single-phase voltage source inverter bridge is connected to the direct current negative output end of the transformer integrated multi-level battery energy storage power converter;

first alternating current output ends of the first single-phase voltage source inverter bridge, the second single-phase voltage source inverter bridge and the third single-phase voltage source inverter bridge are respectively connected to a first group of three-phase cross current terminals on the input side of a six-phase alternating current reactor L1, first alternating current output ends of the fourth single-phase voltage source inverter bridge, the fifth single-phase voltage source inverter bridge and the sixth single-phase voltage source inverter bridge are respectively connected to a second group of three-phase cross current terminals on the input side of a six-phase alternating current reactor L1, a first group of three-phase alternating current terminals on the output side of the six-phase alternating current reactor L1 are respectively connected to one ends of a first filter capacitor CA1, a second filter capacitor CB1 and a third filter capacitor CC1, and a second group of three-phase alternating current terminals on the output side of a six-phase alternating current reactor L1 are respectively connected to one ends of a fourth filter capacitor CA2, a fifth filter capacitor CB2 and a sixth filter capacitor CC 2;

second alternating current output ends of the first single-phase voltage source inverter bridge, the second single-phase voltage source inverter bridge and the third single-phase voltage source inverter bridge are respectively connected to the other ends of the first filter capacitor CA1, the second filter capacitor CB1 and the third filter capacitor CC1, and second alternating current output ends of the fourth single-phase voltage source inverter bridge, the fifth single-phase voltage source inverter bridge and the sixth single-phase voltage source inverter bridge are respectively connected to the other ends of the fourth filter capacitor CA2, the fifth filter capacitor CB2 and the sixth filter capacitor CC 2; two ends of a first filter capacitor CA1, a second filter capacitor CB1 and a third filter capacitor CC1 are respectively connected to six leading-out ends of a first secondary side three-phase winding of a three-winding transformer T, two ends of a fourth filter capacitor CA2, a fifth filter capacitor CB2 and a sixth filter capacitor CC2 are respectively connected to six leading-out ends of a second secondary side three-phase winding of the three-winding transformer T, and a primary side three-phase winding leading-out end of the three-winding transformer T is connected to a power grid;

six leading-out ends of a primary side three-phase winding of the first three-phase energy-taking transformer T1 are respectively connected to first and second alternating current output ends of a first single-phase voltage source inverter bridge, a second single-phase voltage source inverter bridge and a third single-phase voltage source inverter bridge, a secondary side three-phase alternating current end of the first three-phase energy-taking transformer T1 is respectively connected to three alternating current ends of a first three-phase rectifier bridge B1, a direct current positive end of the first three-phase rectifier bridge B1 is connected to a direct current positive end of a fourth single-phase voltage source inverter bridge, a direct current negative end of the first three-phase rectifier bridge B1 is connected to one end of a first direct current filter reactor L2, and the other end of the first direct current filter reactor L2 is connected to a direct current negative end of a sixth single-phase voltage source bridge;

six leading-out ends of a primary side three-phase winding of the second three-phase energy-taking transformer T2 are respectively connected to first and second alternating-current output ends of a fourth single-phase voltage source inverter bridge, a fifth single-phase voltage source inverter bridge and a sixth single-phase voltage source inverter bridge, a secondary side three-phase alternating-current end of the second three-phase energy-taking transformer T2 is respectively connected to three alternating-current ends of a second three-phase rectifier bridge B2, a direct-current positive end of the second three-phase rectifier bridge B2 is connected to one end of a second direct-current filter reactor L3, the other end of the second direct-current filter reactor L3 is connected to a direct-current positive end of the first single-phase voltage source inverter bridge, and a direct-current negative end of the second three-phase rectifier bridge B2 is connected to a direct-current negative end of the third single-phase voltage source inverter bridge.

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