CN112271945A

CN112271945A - Energy storage converter and charge-discharge control method thereof

Info

Publication number: CN112271945A
Application number: CN202011206701.2A
Authority: CN
Inventors: 吴越; 陈满; 雷博; 李勇琦; 郑耀东; 史尤杰; 胡振恺; 许树楷
Original assignee: Research Institute of Southern Power Grid Co Ltd; Peak and Frequency Regulation Power Generation Co of China Southern Power Grid Co Ltd
Current assignee: CSG Electric Power Research Institute; Research Institute of Southern Power Grid Co Ltd; Peak and Frequency Regulation Power Generation Co of China Southern Power Grid Co Ltd
Priority date: 2020-11-02
Filing date: 2020-11-02
Publication date: 2021-01-26

Abstract

The invention discloses an energy storage converter and a charge and discharge control method thereof, wherein the energy storage converter comprises an AC/DC conversion module and a DC/DC conversion module, the AC side of the AC/DC conversion module is connected with an AC power grid through a filter, the DC side of the AC/DC conversion module is connected with the DC/DC conversion module, the DC/DC conversion module comprises a plurality of flyback converters which are connected in series, and the load of each flyback converter is connected with a battery module. In addition, the invention avoids the overcharge and overdischarge of the battery module by controlling the working state of the switch of the flyback converter, thereby effectively solving the problem of battery charge-discharge balance.

Description

Energy storage converter and charge-discharge control method thereof

Technical Field

The invention relates to the technical field of electronic circuits, in particular to an energy storage converter and a charge and discharge control method thereof.

Background

In recent years, with the continuous progress of battery manufacturing technology and power electronic technology, battery energy storage technology has been developed to some extent. Aiming at the problems that the voltage grades of the applied battery modules are not consistent, the grid-connected voltage is far higher than the voltage of a single battery module and the like, a two-stage topology (namely an AC/DC converter and a DC/DC converter) gradually becomes one of the mainstream solutions. In a two-stage topology, a DC/DC converter is responsible for boosting the battery module voltage, and an AC/DC converter is responsible for converting the high DC voltage to high AC voltage suitable for network access. When the battery connected with a certain group of DC/DC converters has a fault, the group of DC/DC converters only needs to be stopped, and the whole system does not need to be stopped. The two-tier topology has greater redundancy and flexibility than a single-tier topology.

However, in the conventional two-stage energy storage converter structure with the parallel connection at the DC, an equalization circuit needs to be added in the battery cluster, and the charging and discharging equalization control cannot be directly performed on all the battery modules. Although the energy storage converter structure that the switch group is connected in series on the DC side can solve the problem of charge-discharge balance of the battery module, there is no isolation structure on the low-voltage DC side, and certain danger is generated to an operator when the battery module is replaced.

Disclosure of Invention

The invention aims to provide an energy storage converter and a charge and discharge control method thereof.

In order to achieve the above object, an embodiment of the present invention provides an energy storage converter, including an AC/DC conversion module and a DC/DC conversion module, where an AC side of the AC/DC conversion module is connected to an AC power grid through a filter, a DC side of the AC/DC conversion module is connected to the DC/DC conversion module, the DC/DC conversion module includes a plurality of flyback converters connected in series, and a load of each flyback converter is connected to a battery module.

Preferably, the flyback converter includes a first capacitor, a second capacitor, a first switch tube, a second switch tube and a transformer; the input side of the transformer is connected with the first capacitor in parallel, and the first switching tube is connected on the input side of the transformer in series; the output side of the transformer is connected with the second capacitor in parallel, and the second switching tube is connected on the output side of the transformer in series; the second capacitor is connected in parallel with the battery module.

Preferably, the first capacitors of the flyback converters are connected in series to form a first capacitor branch of the DC/DC conversion module, a second capacitor branch is disposed on the DC side of the AC/DC conversion module, and the first capacitor branch is connected in parallel with the second capacitor branch.

Preferably, the filter is an LCL filter, the LCL filter includes three-phase filtering branches, one end of each three-phase filtering branch is correspondingly connected to three phases of the AC power grid, and the other end of each three-phase filtering branch is connected to an AC side of the AC/DC conversion module; each phase of filtering branch circuit comprises a first inductor, a second inductor, a third capacitor, a fourth capacitor and a resistor; the fourth capacitor and the resistor are connected in series to form a damping branch circuit, the damping branch circuit and the third capacitor are connected in parallel to form a parallel branch circuit, and the parallel branch circuit is connected between the first inductor and the second inductor.

Preferably, the resistance value of the resistor has a value range of

Wherein R is_daIs the resistance value of the resistor, omega is the resonance frequency of the LCL filter, C_daIs the capacitance value of the fourth capacitor, C_faIs the capacitance value of the third capacitor, L_gaIs an inductance value of the first inductor, L_caIs the inductance value of the second inductor.

Preferably, the AC/DC conversion module is a two-level bridge converter, a T-type three-level converter or a diode-clamped type three-level converter.

Another embodiment of the present invention further provides a charge and discharge control method for an energy storage converter, including the following steps:

acquiring charge and discharge state information of a battery module at a load of the energy storage converter;

when the battery module is in a charging state, acquiring the charging voltage of the battery module;

if the charging voltage of the battery module exceeds a preset first voltage threshold, controlling the flyback converter to enter a preset switch working state so as to enable the battery module to enter a balance control state; or keeping the battery module in a charging state;

when the battery module is in a discharging state, acquiring the discharging voltage of the battery module;

if the discharge voltage of the battery module exceeds a preset second voltage threshold, controlling the flyback converter to enter the switch working state so as to enable the battery module to enter a balance control state; or to maintain the battery module in a discharged state.

Preferably, the controlling the flyback converter to enter a preset switch operating state so that the battery module enters a balanced control state specifically includes:

and controlling a primary side switch tube of the flyback converter to be in a normally open state, and controlling a secondary side switch tube of the flyback converter to be in a normally closed state, so that the battery module enters a balanced control state.

Preferably, after the battery module enters the equalization control state, the method further comprises:

and when detecting that the number of the battery modules in the energy storage converter is greater than a preset number threshold value, taking out the battery modules and replacing the battery modules with new battery modules.

Compared with the prior art, the energy storage converter and the charge-discharge control method thereof provided by the embodiment of the invention have the advantages that the flyback converter is adopted as the DC/DC conversion module, so that the high-voltage side and the low-voltage side of the energy storage converter are isolated, the personal safety of operators during battery replacement is ensured, and the LCL filter is additionally arranged on the alternating current side of the AC/DC converter, so that the suppression effect of the converter on the high-frequency harmonic waves of the network-connected current is greatly improved; in addition, by controlling the switch working state of the flyback converter, the overcharge and the overdischarge of the battery module are avoided, and the problem of battery charge and discharge balance is effectively solved.

Drawings

Fig. 1 is a schematic structural diagram of a first embodiment of an energy storage converter provided by the invention;

fig. 2 is a schematic structural diagram of a second embodiment of an energy storage converter provided in the present invention;

fig. 3 is a schematic structural diagram of a third embodiment of an energy storage converter provided by the invention;

fig. 4 is a schematic flow chart of a charging and discharging control method for an energy storage converter according to a first embodiment of the present invention;

fig. 5 is an equivalent schematic diagram of an embodiment of the battery module 1 of the energy storage converter provided by the invention, which cuts out a circuit at the end of charging/discharging;

fig. 6 is a schematic flow chart of a charging and discharging control method for an energy storage converter according to a second embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, the energy storage converter according to an embodiment of the present invention includes an AC/DC conversion module and a DC/DC conversion module, an AC side of the AC/DC conversion module is connected to an AC power grid through a filter, a DC side of the AC/DC conversion module is connected to the DC/DC conversion module, the DC/DC conversion module includes a plurality of flyback converters connected in series, and a battery module is connected to a load of each flyback converter.

Specifically, the energy storage converter comprises an AC/DC conversion module and a DC/DC conversion module, wherein the AC side of the AC/DC conversion module is connected with an AC power grid through a filter, and the DC side of the AC/DC conversion module is connected with the DC/DC conversion module. The filter functions to suppress high frequency harmonics of the network-in current. The DC/DC conversion module comprises a plurality of flyback converters which are connected in series, namely the input sides of the flyback converters are connected in series to form a branch circuit, and the branch circuit is connected with the direct current side of the AC/DC conversion module in parallel. And a battery module is connected to the load of each flyback converter. That is to say, the first flyback converter is connected with the first battery module, the second flyback converter is connected with the second battery module, … …, the nth flyback converter is connected with the nth battery module, and n is larger than or equal to 1. Preferably, the switching tube of the AC/DC conversion module is a Metal-Oxide-Semiconductor Field-Effect Transistor (MOSFET) or an Insulated Gate Bipolar Transistor (IGBT); and the switching tube in the DC/DC conversion module is a MOSFET.

According to the energy storage converter provided by the embodiment of the invention, the flyback converter is adopted as the DC/DC conversion module, so that the high-voltage side and the low-voltage side of the energy storage converter are isolated, and the personal safety of an operator during battery replacement is ensured.

As an improvement of the above scheme, the flyback converter includes a first capacitor, a second capacitor, a first switch tube, a second switch tube and a transformer; the input side of the transformer is connected with the first capacitor in parallel, and the first switching tube is connected on the input side of the transformer in series; the output side of the transformer is connected with the second capacitor in parallel, and the second switching tube is connected on the output side of the transformer in series; the second capacitor is connected in parallel with the battery module.

Specifically, the flyback converter comprises a first capacitor, a second capacitor and a first switch tube Q_1pA second switch tube Q_1nAnd a transformer; wherein, the input side of the transformer is connected with a first capacitor in parallel, and a first switching tube Q_1pConnected in series on the input side of the transformer, i.e. the input side of the transformer and the first switching tube Q_1pAre connected in series to form a branch circuit, and the branch circuit is connected with the first capacitor in parallel. The output side of the transformer is connected with a second capacitor in parallel, and a second switching tube Q_1nConnected in series on the output side of the transformer. Similarly, the output side of the transformer and the second switch tube Q_1nAre connected in series to form a branch circuit, and the branch circuit is connected with the second capacitor in parallel. The second capacitor is connected in parallel with the battery module.

When the three-phase AC network charges the battery module through the energy storage converter, the primary side switching tube Q_1pIs a main switch tube, i.e. by controlling a first switch tube Q_1pThereby realizing the function of voltage chopping. Secondary side switch tube Q_1nActing as synchronous rectifiers, i.e. as the first switching tube Q_1pSecond switch tube Q when switching on_1nTurning off; first switch tube Q_1pSecond switch tube Q when turning off_1nAnd (4) opening.

When the battery module discharges to the three-phase alternating current network through the energy storage converter, the secondary side switch tube Q_1nIs a main switch tube, i.e. by controlling a second switch tube Q_1nThereby implementing the function of voltage chopping. Primary side switch tube Q_1pActing as a synchronous rectifier, i.e. as the second switching tube Q_1nFirst switch tube Q when switching on_1pTurning off; second switch tube Q_1nFirst switch tube Q when turning off_1pAnd (4) opening.

As an improvement of the above scheme, the first capacitors of the flyback converters are connected in series to form a first capacitor branch of the DC/DC conversion module, a second capacitor branch is disposed on the DC side of the AC/DC conversion module, and the first capacitor branch is connected in parallel with the second capacitor branch.

Specifically, the first capacitor of each flyback converter is connected in series to form a first capacitor branch of the DC/DC conversion module, that is, the first capacitor of the first flyback converter is connected to the first capacitor of the second flyback converter, the first capacitor of the second flyback converter is connected to the second capacitor of the third flyback converter, … …, and the first capacitor of the (n-1) th flyback converter is connected to the second capacitor of the nth flyback converter. And a second capacitor branch is arranged on the direct current side of the AC/DC conversion module, and the first capacitor branch is connected with the second capacitor branch in parallel.

As an improvement of the above scheme, the filter is an LCL filter, the LCL filter includes three-phase filtering branches, one end of each of the three-phase filtering branches is correspondingly connected to three phases of the AC power grid, and the other end of each of the three-phase filtering branches is connected to an AC side of the AC/DC conversion module; each phase of filtering branch circuit comprises a first inductor, a second inductor, a third capacitor, a fourth capacitor and a resistor; the fourth capacitor and the resistor are connected in series to form a damping branch circuit, the damping branch circuit and the third capacitor are connected in parallel to form a parallel branch circuit, and the parallel branch circuit is connected between the first inductor and the second inductor.

Specifically, the filter is an LCL filter which comprises a three-phase filtering branch and a three-phase filtering branchOne end of the circuit is correspondingly connected with three phases of an alternating current power grid respectively, and the other end of the circuit is connected with the alternating current side of the AC/DC conversion module; each phase of filtering branch circuit comprises a first inductor, a second inductor, a third capacitor, a fourth capacitor and a resistor; the fourth capacitor and the resistor are connected in series to form a damping branch circuit, the damping branch circuit and the third capacitor are connected in parallel to form a parallel branch circuit, and the parallel branch circuit is connected between the first inductor and the second inductor. One end of the first inductor is connected with one end of the alternating current power grid, and the other end of the first inductor is connected with the parallel branch circuit. One end of the second inductor is connected with one alternating current side of the AC/DC conversion module, and the other end of the second inductor is connected with the parallel branch circuit. In fig. 1, the first inductance includes L_ga、L_gbAnd L_gcThe second inductor comprises L_ca、L_cbAnd L_ccThe third capacitor comprises C_faThe fourth capacitor comprises C_daThe resistor includes R_da。

As an improvement of the scheme, the value range of the resistance value of the resistor is

It should be noted that, at present, the parameter design method of the LCL filter is mature, but in R_d-C_dIn the design of damping structure parameters, the current method for taking the value of the damping resistor is more complex, and the invention provides a simpler damping resistor R_dThe method of (3).

Specifically, taking the damping resistor of phase a in fig. 1 as an example, the damping resistor resistance may be designed in an angle that the damping branch circuit effectively charges and discharges the resonant voltage component in the resonant capacitor. The LCL filter shown in FIG. 1 is analyzed in two parts, namely by L_ga、L_ca、C_faFormed filter part and R_da、C_daForming a charging and discharging branch. R_da-C_daThe branch may form a low pass filter to filter out spurious components. According to the above analysis, the time corresponding to the resonance frequency can be set to R_da-C_daThe time constant of the branch is three times to five times, the best filtering effect is achieved at the moment

The resistance value of the resistor is in the range of

Wherein R is_daIs the resistance value of the resistor, omega is the resonance frequency of the LCL filter, C_daIs the capacitance value of the fourth capacitor, C_faIs the capacitance value of the third capacitor, L_gaIs the inductance value of the first inductor, L_caIs the inductance value of the second inductor.

As an improvement of the above scheme, the AC/DC conversion module is a two-level bridge converter, a T-type three-level converter, or a diode-clamped three-level converter.

Specifically, the AC/DC conversion module is a two-level bridge converter, a T-type three-level converter, or a diode-clamped three-level converter. When the AC/DC conversion module employs a two-level bridge converter, the energy storage converter is as shown in fig. 1, when the AC/DC conversion module employs a T-type three-level converter, the energy storage converter is as shown in fig. 2, and when the AC/DC conversion module employs a diode-clamped three-level converter, the energy storage converter is as shown in fig. 3.

Referring to fig. 4, a schematic flow chart of a charging and discharging control method of an energy storage converter according to an embodiment of the present invention is shown, where the method includes the following steps:

It should be noted that the charging and discharging control method of each battery module is the same, and only one of the battery modules is taken as an example for description. As for the flyback converter, it is referred to a flyback converter to which the battery module as an example is correspondingly connected, and not a flyback converter to which other battery modules are correspondingly connected.

Specifically, charge and discharge state information of a battery module at the load of the energy storage converter is obtained;

if the charging voltage of the battery module exceeds a preset first voltage threshold, the charging voltage of the battery module approaches the set upper limit value of the charging voltage, and at the moment, the flyback converter needs to be controlled to enter a preset switch working state, so that the battery module enters a balance control state; or continue to maintain the battery module in a charged state. When the battery module enters the equalization control state, namely the battery module is not charged and is not discharged outwards, the battery module can be switched out of the charging circuit at the moment, and the battery module to be charged is replaced. When the battery module is kept in a charging state, because the battery module is close to the end of charging, the flyback converter needs to be controlled to be in a constant voltage output state, so that the battery module is not powered down.

if the discharge voltage of the battery module exceeds a preset second voltage threshold, the discharge voltage of the battery module approaches a lower limit value of the discharge voltage, and at the moment, the flyback converter needs to be controlled to enter a preset switch working state, so that the battery module enters a balance control state; or to continue to maintain the battery module in a discharged state. When the battery module enters the balance control state, the battery module can be switched out of a charging circuit to replace the battery module to be discharged. When the battery module is in a discharge state, the flyback converter needs to be controlled to be in a constant voltage output state because the battery module is close to the end of discharge, so that the direct current side of the flyback converter maintains a stable output voltage. As an improvement of the above scheme, the controlling the flyback converter to enter a preset switch operating state so as to enable the battery module to enter a balanced control state specifically includes:

Specifically, a primary side switch tube of the flyback converter is controlled to be in a normally open state, and a secondary side switch tube of the flyback converter is controlled to be in a normally closed state, so that the battery module enters a balanced control state.

It is worth reminding that, keeping the battery module in the charging state, the primary side switch of the flyback converter needs to be continuously controlled to be turned on or off, and the secondary side switch tube of the flyback converter is synchronously controlled to be correspondingly turned off or on, so that the battery module is kept in the charging state. That is, the primary side switching tube Q of the flyback converter is controlled_1pIs a main switch tube and is controlled by a control Q_1pThe high frequency of the tube turns on/off to thereby achieve the function of voltage chopping. Secondary side switch tube Q_1nActing as a synchronous rectifier, i.e. when Q is_1pQ when the tube is opened_1nThe tube is shut off; q_1pQ at tube turn-off_1nThe tube is opened.

And keeping the battery module in a discharging state, continuously controlling the secondary side switch of the flyback converter to be switched on or switched off, and synchronously controlling the primary side switch tube of the flyback converter to be correspondingly switched off or switched on so as to keep the battery module in the discharging state. That is, the secondary side switching tube Q of the flyback converter is controlled_1nIs a main switch tube and is controlled by a control Q_1nThe on/off time of the tube is thereby obtainedThe function of voltage chopping is now present. Primary side switch tube Q_1pActing as a synchronous rectifier, i.e. when Q is_1nQ when the tube is opened_1pThe tube is shut off; q_1nQ at tube turn-off_1pThe tube is opened.

As an improvement of the above scheme, after the battery module enters the equalization control state, the method further includes:

Specifically, after the battery module enters the equalization control state, the battery module can be switched out of the energy storage converter, but before the battery module is switched out, the number of the battery modules in the energy storage converter needs to be detected, and since a certain number of batteries are always required on the direct current side of the circuit to support the direct current voltage, a number threshold value can be preset.

When the number of the battery modules in the energy storage converter is detected to be larger than a preset number threshold, if the battery modules need to be replaced, the battery modules can be taken out, and new battery modules can be replaced. Referring to fig. 5, it is an equivalent schematic diagram of a circuit cut-out of the battery module 1 of the energy storage converter at the end of charging/discharging according to the embodiment of the present invention. And when the taken out battery module is fully charged, the battery module to be charged is replaced, and after the battery module is replaced, the switching working state of the flyback converter is changed, so that the flyback converter enters the charging state again. And when the taken out battery module is discharged, replacing the battery module to be discharged, and changing the switch working state of the flyback converter after replacing the battery module so as to enable the flyback converter to enter the discharging state again.

In order to deepen understanding of the charging and discharging control method of the energy storage converter, the embodiment of the invention further provides a simple flow diagram of the charging and discharging control method of the energy storage converter, and the diagram is shown in fig. 6.

In summary, according to the energy storage converter and the charge and discharge control method thereof provided by the embodiments of the present invention, the LCL filter is additionally installed on the AC side of the AC/DC converter, so that the high-frequency harmonic suppression effect of the converter on the network access current is greatly increased. The LCL filter is used, the size of the filter is reduced, and meanwhile, the practicability of the LCL filter is improved by the provided simple calculation method of the damping resistance. In addition, the DC/DC converter adopts the bidirectional flyback converter with isolation and a plurality of modules with primary sides connected in series, so that the low-voltage side is isolated from the high-voltage side, and the system safety is improved; the turn ratio of the transformer of the flyback converter can be adjusted according to different rated voltages of the connected module batteries, so that the application range of the energy storage converter to various module batteries is enlarged; the high-voltage side and the low-voltage side of the energy storage converter are isolated, so that the transmission path of electromagnetic noise in a circuit can be cut off, and the current-voltage waveform quality is improved. According to the charge and discharge control method of the energy storage converter, disclosed by the invention, the overcharge and the overdischarge of the module battery are avoided to a certain extent, and the service life of the battery module is prolonged; meanwhile, the DC/DC converter has an isolation function, so that the battery module can be replaced more safely when the converter is switched out of the battery, and certain flexibility is realized.

While the foregoing is directed to the preferred embodiment of the present invention, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention.

Claims

1. The energy storage converter is characterized by comprising an AC/DC conversion module and a DC/DC conversion module, wherein the AC side of the AC/DC conversion module is connected with an AC power grid through a filter, the DC side of the AC/DC conversion module is connected with the DC/DC conversion module, the DC/DC conversion module comprises a plurality of flyback converters which are connected in series, and a battery module is connected to the load of each flyback converter.

2. The energy storage converter according to claim 1, wherein the flyback converter comprises a first capacitor, a second capacitor, a first switch tube, a second switch tube and a transformer; the input side of the transformer is connected with the first capacitor in parallel, and the first switching tube is connected on the input side of the transformer in series; the output side of the transformer is connected with the second capacitor in parallel, and the second switching tube is connected on the output side of the transformer in series; the second capacitor is connected in parallel with the battery module.

3. The energy storage converter as claimed in claim 2, wherein said first capacitor of each said flyback converter is connected in series to constitute a first capacitor branch of said DC/DC conversion module, and a second capacitor branch is provided on a DC side of said AC/DC conversion module, and said first capacitor branch is connected in parallel with said second capacitor branch.

4. The energy storage converter according to claim 1, wherein the filter is an LCL filter, the LCL filter includes three-phase filter branches, one end of each of the three-phase filter branches is correspondingly connected to three phases of the AC power grid, and the other end of each of the three-phase filter branches is connected to an AC side of the AC/DC conversion module; each phase of filtering branch circuit comprises a first inductor, a second inductor, a third capacitor, a fourth capacitor and a resistor; the fourth capacitor and the resistor are connected in series to form a damping branch circuit, the damping branch circuit and the third capacitor are connected in parallel to form a parallel branch circuit, and the parallel branch circuit is connected between the first inductor and the second inductor.

5. The energy storing converter as claimed in claim 4, wherein the resistance value of said resistor is in the range of

6. An energy storing converter as claimed in any one of claims 1 to 5, wherein said AC/DC conversion module is a two-level bridge converter, a T-type three-level converter or a diode-clamped three-level converter.

7. A method for controlling charging and discharging of a power converter according to any of claims 1 to 6, characterized in that it comprises the following steps:

8. The charging and discharging control method of the energy storage converter according to claim 7, wherein the step of controlling the flyback converter to enter a preset switching operation state so as to enable the battery module to enter a balance control state specifically comprises the steps of:

9. The charging and discharging control method of the energy storage converter according to claim 7, further comprising, after the battery module enters the balancing control state: