CN209844564U - Pre-synchronization device for switching off-grid to grid-connected micro-grid based on multiple energy storage converters - Google Patents

Abstract

The utility model provides a little electric wire netting is from pre-synchronization device that is incorporated into power networks that nets based on many energy storage converters, each energy storage converter's local controller is connected to little electric wire netting central controller, wherein, local controller is in coordination little electric wire netting central controller uses the angular frequency and the voltage of big electric wire netting to adjust the voltage and the angular frequency of little electric wire netting generating line as the target little electric wire netting the little electric wire netting generating line with after the angular frequency deviation and the voltage deviation of big electric wire netting are less than the default, in coordination little electric wire netting central controller uses the phase place of big electric wire netting to adjust the phase place of little electric wire netting the little electric wire netting generating line with after the angular frequency deviation, the voltage deviation, the phase deviation three of big electric wire netting all is less than the default, will it incorporates into in the big electric wire.

Description

Pre-synchronization device for switching off-grid to grid-connected micro-grid based on multiple energy storage converters

Technical Field

The utility model relates to a little electric wire netting control field especially relates to a little electric wire netting of many energy storage converters changes synchronizer in advance that is incorporated into power networks from the net.

Background

In a microgrid, a distributed Power supply is generally connected to the microgrid for energy exchange after performing electric energy conversion through a Power Converter System (PCS) based on a Power electronics technology. The energy conversion device includes various forms such as DC/AC, DC/DC and the like.

The control strategies for the energy conversion device in steady-state operation are mainly divided into a PQ control mode aiming at outputting active power/reactive power, a Vf control mode aiming at providing stable ac bus voltage support, and a droop control mode extended according to a linear relationship between the output active power/frequency and the reactive power/voltage of the conventional generator.

The traditional droop control mode in the microgrid has the following disadvantages:

(1) the droop control mode mostly takes the output voltage of the inverter as a control target, and due to the reason of line voltage drop, the output voltage at the generator end of the energy conversion device is unstable, the reference voltage of the energy conversion device is difficult to maintain on a uniform amplitude value, the stability of the voltage of the microgrid bus is directly influenced, and the quality of electric energy is reduced.

(2) Under the condition that a plurality of inverters are connected to the microgrid bus, because the lengths of lines from all the distributed power supplies to the common connection point are inconsistent, the connection line impedances of the distributed power supplies are different, and therefore reactive power cannot be reasonably distributed.

(3) The microgrid can be converted from off-grid operation to grid-connected operation with an external large power grid, but voltage and phase between the microgrid and the large power grid can deviate, and larger impact current can be generated when the off-grid operation is converted into the grid-connected operation at improper moment.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide a little electric wire netting is from grid to synchronization device in advance who is incorporated into the power networks based on many energy storage converters to make the little electric wire netting can be stably from the operation of leaving the grid to be converted into the operation of being incorporated into the power networks.

In order to solve the above technical problem, an aspect of the present invention provides a pre-synchronization device for converting an off-grid to a on-grid of a microgrid based on multiple energy storage converters, the pre-synchronization device includes a central controller of the microgrid, each of the energy storage converters includes a dc power supply, a three-phase inverter circuit, a filter inductor and a filter capacitor connected in sequence, the filter capacitor is connected to a common bus of the microgrid through a transformer, each of the energy storage converters is connected to a local controller, the local controller of each energy storage converter is connected to the central controller of the microgrid, wherein the local controller adjusts the voltage and the angular frequency of the microgrid bus with the angular frequency and the voltage of the microgrid as targets by the central controller, and adjusts the phase of the microgrid bus with the phase of the microgrid as a target after the angular frequency deviation and the voltage deviation of the microgrid bus and the microgrid are less than a preset value, and after the angular frequency deviation, the voltage deviation and the phase deviation of the micro-grid bus and the large power grid are all smaller than preset values, the micro-grid is merged into the large power grid.

The utility model discloses an in an embodiment, local controller is in coordination the microgrid central controller uses the angular frequency and the voltage of big electric wire netting as the voltage and the angular frequency of target to the microgrid generating line to adjust and include: the microgrid central controller calculates the adjustment quantity of active power and reactive current according to the voltage and angular frequency of the microgrid common bus, and sends the adjustment quantity of the active power and the reactive current to the local controllers of the energy storage converters according to the distribution coefficients; and each local controller adjusts the electromotive force e of the three-phase inverter circuit according to the distributed active power regulating quantity and reactive current regulating quantity until the deviation between the voltage and angular frequency of the microgrid public bus and the voltage and angular frequency of the large power grid is smaller than a preset value.

In an embodiment of the present invention, the local controller includes a droop controller and a dual-ring controller; the droop controller outputs the target output voltage U of the energy storage converter according to the distributed reactive current regulation quantity_crefDroop control and target output angular frequency omega of the energy storage converter according to the distributed active power regulation_refCarrying out droop control; the dual-loop controller outputs current i according to the filter inductor₁A voltage U of a target output of the droop controller_crefAnd target output angular frequency ω_refAnd generating a driving signal, and adjusting the electromotive force e of the three-phase inverter circuit by the energy storage converter according to the driving signal.

The present invention provides an embodiment, wherein each of the local controllers adjusts the electromotive force e of the three-phase inverter circuit according to the active power regulation and the reactive current regulation distributed from large to small according to the capacity of the corresponding energy storage converter.

The utility model discloses an in the embodiment, the microgrid central controller calculates the formula that the regulating variable of active power and reactive current adopted according to the voltage and the angular frequency of the public generating line of microgrid is:

ΔP_M＝(k_ω1+k_ω2/s)*(ω_G-ω_M)

ΔI_Q＝(k_u1+k_u2/s)*(U_G-U_M)

wherein, Δ P_MRepresenting the total regulation of active power, k_ω1Representing the proportionality coefficient, k, of a common bus frequency PI controller_ω2/s represents the integral coefficient, ω, of the common bus frequency PI controller_GRepresenting angular frequency, omega, of a large power network_MRepresenting angular frequency, Δ I, of a microgrid common bus_QRepresenting the total regulation of the reactive current, k_u1Representing the proportionality coefficient, k, of a common bus voltage PI controller_u2The/s represents the integral coefficient of the common bus voltage PI controller, U_GRepresenting the voltage, U, of a large power network_MAnd the voltage of the microgrid common bus is represented.

The utility model discloses an in an embodiment, local controller is in coordination the microgrid central controller uses the phase place of big electric wire netting as the phase place of target to adjust the microgrid generating line includes: to microgrid common bus voltage U_MCarrying out abc/dq conversion by taking the phase of a large power grid as reference to obtain U_MdAnd U_MqTarget 0 to U_MqAnd (6) carrying out adjustment.

Compared with the prior art, the utility model has the advantages of it is following: when the microgrid is switched from off-grid operation to grid-connected operation with an external large power grid, the voltage, the frequency and the phase of the microgrid are adjusted and controlled, so that the voltage, the frequency and the phase of a bus meet the grid-connected requirement, and the microgrid can be stably switched from off-grid operation to grid-connected operation.

Drawings

In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, embodiments of the present invention are described in detail below with reference to the accompanying drawings, wherein:

fig. 1 is a schematic diagram of a microgrid configuration of a multi-energy storage converter according to an embodiment of the present invention;

fig. 2 is a logic block diagram of a pre-synchronization apparatus for converting an off-grid to a on-grid of a micro-grid according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a two-machine parallel microgrid configuration;

fig. 4A is a schematic diagram of a frequency of a common bus in a process of converting the off-grid to the on-grid of the microgrid in fig. 3;

fig. 4B is a schematic waveform diagram of [1s, 1.5s ] common bus voltage in the process of converting the off-grid to the on-grid of the microgrid in fig. 3;

fig. 4C is a waveform diagram of the common bus voltage in the interval [2s, 2.5s ] in the process of converting the off-grid to the on-grid of the microgrid in fig. 3;

FIG. 5A is a schematic waveform of the combined output active power variation of two energy storage converters of the micro-grid in FIG. 3;

FIG. 5B is a schematic waveform diagram of the change of the reactive power output by the two energy storage converters of the microgrid in FIG. 3;

fig. 6 is a schematic diagram of an energy storage converter according to an embodiment of the present invention;

fig. 7 is a logic block diagram of a dual-loop controller according to an embodiment of the present invention;

fig. 8 is a logic block diagram of a dual-loop controller according to another embodiment of the present invention.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those specifically described herein, and thus the present invention is not limited by the specific embodiments disclosed below.

As used in this application and the appended claims, the terms "a," "an," "the," and/or "the" are not intended to be inclusive in the singular, but rather are intended to be inclusive in the plural unless the context clearly dictates otherwise. In general, the terms "comprises" and "comprising" merely indicate that steps and elements are included which are explicitly identified, that the steps and elements do not form an exclusive list, and that a method or apparatus may include other steps or elements.

It will be understood that when an element is referred to as being "on," "connected to," "coupled to" or "contacting" another element, it can be directly on, connected or coupled to, or contacting the other element or intervening elements may be present. In contrast, when an element is referred to as being "directly on," "directly connected to," "directly coupled to" or "directly contacting" another element, there are no intervening elements present. Similarly, when a first component is said to be "in electrical contact with" or "electrically coupled to" a second component, there is an electrical path between the first component and the second component that allows current to flow. The electrical path may include capacitors, coupled inductors, and/or other components that allow current to flow even without direct contact between the conductive components.

Fig. 1 is a schematic diagram of a microgrid structure of a multi-energy storage converter according to an embodiment of the present invention. As shown in fig. 1, the structure of the microgrid 100 comprises i lines, each of which is connected to a microgrid central controller 150. The microgrid 100 is connected to a large power grid through a switch bank 130. Only the circuit 100a is described here, and other circuits may have the same structure as the circuit 100a and are not described herein again. Line 100a includes a storage converter 110, a transformer 120, a switch 130, and a common bus 140. The energy storage converter 110 includes a dc power supply 111, a three-phase inverter circuit 112, a filter inductor 113 and a filter capacitor 114, which are connected in sequence. The filter capacitor 114 is connected to the common bus 140 of the microgrid via a transformer 120. The energy storage converter 110 is connected with a local controller 115, and the local controller 115 of the energy storage converter 110 is connected with a microgrid central controller 150.

The local controller 115 cooperates with the microgrid central controller 150 to adjust the voltage and the angular frequency of the public bus 140 of the microgrid with the angular frequency and the voltage of the large power grid as targets, after the angular frequency deviation and the voltage deviation of the public bus 140 and the large power grid are smaller than preset values, the local controller 115 cooperates with the microgrid central controller 150 to adjust the phase of the public bus 140 with the phase of the large power grid as targets, and after the angular frequency deviation, the voltage deviation and the phase deviation of the public bus 140 and the large power grid are smaller than preset values, the microgrid 100 is incorporated into the large power grid.

In one embodiment, the microgrid central controller 150 calculates the adjusted amounts of active power and reactive current based on the voltage and angular frequency of the common bus 140 and sends the adjusted amounts of active power and reactive current to the local controllers 115 of the energy storage converters 110 according to the distribution coefficients. The local controller 115 adjusts the electromotive force e of the three-phase inverter circuit 112 according to the distributed active power adjustment amount and reactive current adjustment amount until the deviation between the voltage and angular frequency of the common bus 140 and the voltage and angular frequency of the large power grid is smaller than a preset value.

It should be noted that, when the microgrid is switched from the off-grid to the on-grid, in consideration of the existence of network transmission and various error conditions, the frequency and voltage may still not meet the grid-connection requirement after secondary frequency modulation and secondary voltage regulation, so in n lines included in the microgrid 100, each local controller may adjust the electromotive force e of the three-phase inverter circuit according to the distributed active power regulation amount and reactive current regulation amount from large to small according to the capacity of the energy storage converter corresponding to each line, so as to meet the grid-connection requirement.

In one embodiment, the local controller 115 may include a droop controller 115a and a dual-ring controller 115 b: droop controller 115a adjusts the amount of distributed reactive current Δ I_QTarget output voltage U to energy storage converter 110_crefDroop control and regulation of delta P in dependence on the distributed active power_MTarget output angular frequency omega to energy storage converter 110_refAnd (5) carrying out droop control. The dual-loop controller 115b outputs a current i according to the filter inductor 113₁A target voltage U of the droop controller 115a_crefAnd angular frequency ω_refThe storage converter 110 generates a driving signal, and adjusts the electromotive force e of the three-phase inverter circuit 112 according to the driving signal.

The formula used by the microgrid central controller 150 to calculate the adjustment amount of the active power and the reactive current according to the voltage and the angular frequency of the common bus 140 may be:

ΔP_M＝(k_ω1+k_ω2/s)*(ω_G-ω_M) (1)

ΔI_Q＝(k_u1+k_u2/s)*(U_G-U_M) (2)

in the formulas (1) and (2), Δ P_MRepresenting the total regulation of active power, k_ω1Representing the proportionality coefficient, k, of a common bus frequency PI controller_ω2The/s represents the integral coefficient of the common bus frequency PI controller, omega_GRepresenting angular frequency, omega, of a large power network_MRepresenting angular frequency, Δ I, of a microgrid common bus_QRepresenting the total regulation of the reactive current, k_u1Representing the proportionality coefficient, k, of a common bus voltage PI controller_u2The/s represents the integral coefficient of the common bus voltage PI controller, U_GRepresenting the voltage, U, of a large power network_MAnd the voltage of the microgrid common bus is represented.

Fig. 2 is a logic block diagram of a microgrid central controller 200 of a pre-synchronization apparatus for switching a microgrid from an off-grid to a grid-connected state according to an embodiment of the present invention. The method for adjusting the phase of the microgrid bus by the microgrid central controller in the pre-synchronization device by taking the phase of the large power grid as a target comprises the following steps: to microgrid common bus voltage U_MCarrying out abc/dq conversion by taking the phase of a large power grid as reference to obtain U_MdAnd U_MqTarget 0 to U_MqAnd (6) carrying out adjustment. The pre-synchronization device in this embodiment may adjust the phase of the microgrid bus by using the phase of the large power grid as a target through the logic block diagram of fig. 2, but is not limited to fig. 2. The composition and adjustment process of the pre-synchronization apparatus 200 will be described with reference to fig. 2.

As shown in fig. 2, the microgrid central controller 200 comprises a first adder 211, a first PI controller 221, and a third switch K connected in sequence₃First change-over switches K connected in sequence₁A second adder 212, a second PI controller 222 and a third adder 213, and a second change-over switch K connected in sequence₂A fourth adder 214, and a third PI controller 223.

The positive input of the first adder 211 is input U_GqSo that U is_Gq0, negative input terminal U_MqThe output end of the first adder 211 is input to the first PI controller 221, and the output end of the first PI controller 221 is directly connected to the third switch K₃The output terminal of the first PI controller 221 passes through the third switch K₃To a first positive input of the third adder 213. First change-over switch K₁Connected to the positive input terminal of the second adder 212 when the first switch K is turned on₁The positive input ω of the second adder 212 when set to 1_Mref(ω_MrefTarget output angular frequency for microgrid common bus) when first change-over switch K₁Set to 2, the positive input ω of the second adder 212_G(ω_GThe output angular frequency of a large grid). Negative input ω of second adder 212_MThe output terminal of the second adder 212 is input to a second PI controller 222, which controls the second PIAn output terminal of the third adder 222 is input to a second positive input terminal of the third adder 213. Second change-over switch K₂Is connected to the positive input terminal of the fourth adder 214 when the second switch K is turned on₂The positive input U of the fourth adder 214 when set to 1_Mref(U_MrefTarget output voltage for microgrid common bus) when the second change-over switch K is turned on₂The positive input terminal of the fourth adder 214 inputs U when set to 2_G(U_GThe output voltage of the large grid). Negative input terminal of fourth adder 214 inputs U_MThe output terminal of the fourth adder 214 is input to the third PI controller 223, and the output terminal of the second PI controller 222 is input to the second positive input terminal of the third adder 213.

When the pre-synchronization device 200 starts to work, first, the first switch K is turned on₁And a second change-over switch K₂Set to 2 closed, microgrid central controller 200 to ω_GAnd U_GAdjusting, and closing a third change-over switch K when the deviation value of the output voltage and the angular frequency of the large power grid and the microgrid public bus is smaller than a set value₃And carrying out phase adjustment. The phase adjustment is used for adjusting the phase of the microgrid bus by the microgrid central controller by taking the phase of a large power grid as a target, and comprises the following steps: to microgrid common bus voltage U_MPerforming abc/dq transformation to obtain U_MdAnd U_MqTarget 0 to U_MqAnd (6) carrying out adjustment. After adjustment, the adjustment value is set to Δ P_MAnd Δ I_QAre assigned to the respective energy storage converter on the respective line.

Fig. 3, 4A-4C and fig. 5A-5B are schematic diagrams illustrating simulation results of a pre-synchronization device for off-grid to on-grid conversion of a micro-grid based on a multi-energy-storage converter according to an embodiment of the present invention. Fig. 3 is a schematic structural diagram of a two-machine parallel microgrid. The whole off-grid to grid connection process lasts from 1s to 3.5s, fig. 4A is a schematic diagram of the frequency of a common bus in the off-grid to grid connection process of the microgrid in fig. 3, fig. 4B is a schematic diagram of the waveform of the voltage of the common bus in the interval of [1s, 1.5s ] in the off-grid to grid connection process of the microgrid in fig. 3, fig. 4C is a schematic diagram of the waveform of the voltage of the common bus in the interval of [2s, 2.5s ] in the off-grid to grid connection process of the microgrid in fig. 3, fig. 5A is a schematic diagram of the waveform of the active power change jointly output by two energy storage converters of the microgrid in fig. 3, and fig. 5B is a schematic diagram of the waveform of the reactive power change jointly output by two energy storage converters of the.

As shown in fig. 3, the microgrid 300 is operated in parallel to a common bus 330 by lines 300a and 300b on which two energy storage converters 310 and 320 are respectively located. The lines 300a and 300b are both connected to the microgrid central controller 360. A load 350 is coupled to the right side of the common bus 330. The rated power of the energy storage converter 310 is 500kW, the rated power of the energy storage converter 320 is 250kW, the filter inductance L11 of the line 300a is 0.1mH, the filter inductance L12 of the line 300b is 0.2mH, the filter capacitances C of the two lines are both 0.5 muF, and the total line inductance X of the line 300a_t10.03mH, total path inductive reactance X of line 300b_t2The load is 0.06mH, the active load of the connected load 350 is 150kW, and the reactive load is 150 kVar. The voltage of the large power grid side is 400V, and the frequency is 50 Hz. In the simulation process, the grid connection is started at 1.2s, and the success of the grid connection is measured at 2.28 s.

As shown in fig. 4A-4C, it can be seen from the waveform diagrams that the voltage of the common bus 330 of the microgrid 300 is always stabilized at a stable value between 0V and 300V in the process of switching the microgrid 300 from grid to grid, and at 1.2s, the bus voltage is significantly increased, the frequency of the common bus 330 is always stabilized at 50Hz, and both the voltage and the frequency of the common bus 330 meet the grid-connection requirement.

As shown in fig. 5A-5B, it can be seen from the waveform diagrams that the two energy storage converters 310 and 320 can stably and jointly output active power and reactive power when the microgrid 300 is in an off-grid mode and after the grid connection is successful, and the two energy storage converters 310 and 320 work together well.

The utility model discloses a local controller and microgrid central controller in every parallel circuit are connected with each energy storage converter, have realized accomplishing reactive power's according to the capacity distribution through the droop curve, and this distribution does not receive the different influence of each circuit impedance. The structure and control principle of the local controller and the microgrid central controller are explained in detail below.

The droop control mode is a differential control mode, and under the condition that a load exists in a system, the frequency and the amplitude of the output voltage of the energy storage converter naturally droop along the droop curve of the energy storage converter. Therefore, in order to improve the power supply quality of the microgrid system, voltage frequency recovery control needs to be adopted.

The embodiment can adopt the coordination control of a plurality of energy storage converters, and the principle of the coordination control is as follows:

continuing to refer to fig. 1, taking the energy storage converter 110 as an example, the active equation and the reactive equation output by the energy storage converter 110 to the bus 140 are respectively:

in the formulas (3) and (4), P is the active power output by the energy storage converter 110, Q is the reactive power output by the energy storage converter 110, and U_cFor the output voltage, U, of the energy-storing converter 110_MIs the bus 140 voltage, X_tDelta is U for total inductive reactance of the route_cAnd U_MThe phase angle difference of the two voltages.

Equation (5) can be transformed from equation (4) as follows:

in the formula (5), I_QIs the reactive current output by the energy storage converter 110. As can be seen from equation (5), I_QCan replace Q to U_cAnd (5) controlling. The droop control strategy adopted for the microgrid bus voltage is as follows:

in the formula (6), the first and second groups,rated voltage, U, for no-load bus 140_MIs a bus bar 1The voltage value is 40, and y is a droop coefficient. From equations (5) and (6), equation (7) can be derived as follows:

to U_CPerforming a non-difference control so that U_C＝U_crefFrom equation (5) and equation (7), equation (8) can be derived as follows:

the simplified equation (8) can be obtainedAfter further deformation, the following results are obtained:

wherein,substituting it into equation (9) gives the following equation:

in the formula (10), I_Q，1Representing the reactive current, I, output by the 1 st energy-storing converter_Qmax，1Representing the maximum reactive current, I, output by the 1 st energy-storing converter_Q，2Representing the reactive current, I, output by the 2 nd energy-storing converter_Qmax，2Representing the maximum reactive current, I, output by the 2 nd energy-storing converter_Q，iRepresenting the reactive current, I, output by the ith energy-storing converter_Qmax，iThe maximum reactive current output by the ith energy storage converter is shown,

according to the formula (10), the reactive current I output by each energy storage converter_Q，iAnd maximum output reactive current I_Qmax，iHave the same ratio ofThe utility model discloses idle current I in this embodiment_Q，iCan be scaled by sag curve_Qmax，iDistributed to lines, i.e. dependent on bus voltage U_MVariation of the energy-storage converters I to their own capacities I_Qmax，iThe reactive current I is output in the same proportion_Q，iAnd is not affected by the impedance difference of each line.

In the microgrid configuration shown in fig. 1, the local controller 115 may include a droop controller 115a and a dual-ring controller 115 b. Droop controller 115a adjusts the amount of distributed reactive current Δ I_QTarget output voltage U to energy storage converter 110_crefDroop control and regulation of delta P in dependence on the distributed active power_MTarget output angular frequency omega to energy storage converter 110_refAnd (5) carrying out droop control. The dual-loop controller 115b outputs the current i according to the filter inductor 213₁A target voltage U of the droop controller 115a_crefAnd angular frequency ω_refThe storage converter 110 generates a driving signal, and adjusts the electromotive force e of the three-phase inverter circuit 112 according to the driving signal. Each droop controller adjusts the amount of delta I according to the distributed reactive current_QTarget output voltage U to energy storage converter_crefDroop control and target output angular frequency omega of energy storage converter according to distributed active power adjustment_MrefThe formula adopted for droop control is as follows:

ω_cref，i＝ω^*-m_i(P_i-a_iΔP_M) (10)

in the formulae (10) to (13), ω_cref，iRepresenting the target output angular frequency, omega, at the filter capacitor of the ith energy-storage converter^*Representing nominal angular frequency, m_iAnd n_iRepresenting the droop coefficient, P, of the ith energy-storing converter_iRepresenting the active power output by the ith energy-storing converter, a_iAnd b_iRepresenting the distribution coefficient, Δ P, of the i-th energy-storing converter_MRepresenting the total regulation of active power, U_cref，iRepresenting the target output voltage at the filter capacitor of the ith energy storage converter,indicating the rated voltage of the bus, X_t，iIndicating the total line inductance, I, of the ith energy-storing converter_Q，iIndicating reactive current, Δ I, output by the ith energy-storing converter_QRepresenting the total regulated amount of reactive current.

Each droop controller adjusts the amount of delta I according to the distributed reactive current_QTarget output voltage U to energy storage converter_crefCarry out droop control to and carry out the formula that droop control adopted according to the output angular frequency omega of distributed active power regulating variable energy storage converter the utility model discloses a can alternate in the different embodiments. In another embodiment of the present invention, the reactive current reference value I is introduced based on formulas (5) to (8)_QrefAs the reactive current I output by the energy storage converter 110_QTarget value of, active power reference value P_refAs the target value of the active power P output by the energy storage converter 110, the formula adopted by the improved droop controller 115a for droop control is as follows:

ω_cref，i＝ω^*-m_i(P_i-P_ref，i-a_iΔP_M) (14)

in the formulae (14) to (17), ω_cref，iRepresenting the target output angular frequency, omega, at the filter capacitor of the ith energy-storage converter^*Representing nominal angular frequency, m_iAnd y_iRepresenting the droop coefficient, P, of the ith energy-storing converter_iRepresenting the active power output by the ith energy-storing converter, a_iAnd b_iRepresenting the distribution coefficient, Δ P, of the i-th energy-storing converter_MRepresenting the total regulation of active power, U_cref，iRepresenting the target output voltage at the filter capacitor of the ith energy storage converter,indicating the rated voltage of the bus, X_t，iIndicating the total line inductance, I, of the ith energy-storing converter_Q，iIndicating reactive current, Δ I, output by the ith energy-storing converter_QRepresenting the total regulation of reactive current, P_ref，iRepresenting the active power reference, I, of the ith energy-storing converter output_Qref，iAnd the reactive current reference value output by the ith energy storage converter is represented.

Fig. 6 is a schematic diagram of an energy storage converter according to an embodiment of the present invention. The energy storage converter and its local controller of this embodiment are explained below with reference to fig. 6. As shown in fig. 6, the microgrid configuration 600 comprises an energy storage converter 610, a transformer 620, a switch 630 and a common bus 640. The energy storage converter 610 includes a dc power supply 611, a three-phase inverter circuit 612, a filter inductor 613, and a filter capacitor 614 connected in sequence. The filter inductor 613 and the filter capacitor 614 constitute an LC filter circuit. The transformer 620 is connected to the energy storage converter 610, and the energy storage converter 610 is connected to the common bus 640 through the switch 630. In fig. 6, a local controller 615 is connected to the energy storage converter 610. The local controller 615 includes a droop controller 615a and a dual ring controller 615 b. The droop controller 615a can be based on the reactive current output by the energy storage converter 610I_QTarget output voltage U to energy storage converter 610_crefDroop control is performed and the output angular frequency ω of the energy storage converter 610 can be adjusted according to the active power P output by the energy storage converter 610_refAnd (5) carrying out droop control. The dual-loop controller 615b can be based on the output current i of the filter inductor 613₁Target output voltage U of droop controller 615a_crefAnd target output angular frequency ω_refGenerating a driving signal, the energy storage converter 610 adjusts the electromotive force e of the three-phase inverter circuit 616 according to the driving signal, and outputs a stable voltage U of the bus 640_m。

Deducing according to the above formula, the utility model discloses an embodiment has improved the reactive power regulation in to current droop control strategy, the utility model discloses a formula that droop controller 615a adopted in an embodiment carries out droop control is:

ω_ref＝ω^*-mP (19)

in the formulas (18) and (19), U_crefFor a target output voltage of the energy storage converter 610,rated voltage, X, for no-load bus 640_tFor total inductive reactance of the route, m and y are sag coefficients, I_QFor the reactive current, ω, output by the energy storage converter 610_refIs the target angular frequency, ω^*At the rated angular frequency, P is the active power output by the energy storage converter 610.

The droop controller 615a may use a formula that may be transformed in different embodiments. In the present invention, the droop control strategy can introduce the reference value of reactive power I on the basis of the formulas (18) and (19)_QrefAs reactive current I output by the energy storage converter 610_QTarget value of, active power reference value P_refAs the target value of the active power P output by the energy storage converter 610, the formula adopted by the improved droop controller 615a for droop control is as follows:

ω_ref＝ω^*-m(P-P_ref) (21)

in the formulas (20) and (21), U_crefFor a target output voltage of the energy storage converter 610,rated voltage, X, for no-load bus 640_tFor total inductive reactance of the route, m and y are sag coefficients, I_QFor the reactive current, ω, output by the energy storage converter 610_refIs the target angular frequency, ω^*At the rated angular frequency, P is the active power output by the energy storage converter 610.

According to the formulas (20), (21), the dual-loop controller 615b can output the current i according to the filter inductor₁Voltage U output from droop controller 615a_cGenerating a driving signal according to the sum angular frequency omega, adjusting the electromotive force e of the three-phase inverter circuit 616 by the energy storage converter 610 according to the driving signal, and outputting a stable bus voltage U_M。

Fig. 7 is a logic block diagram of a dual-ring controller in the control device of the energy storage converter of the present invention. As shown in fig. 7, in order to control the microgrid system, the output current i of the filter inductor needs to be adjusted₁Energy storage converter output voltage U_cConverting abc/dq coordinates to obtain i_1d、i_1qAnd U_cd、U_cqThe dual-ring controller 700 includes a first adder 711, a first PI controller 721, a second adder 712, a second PI controller 722, a third adder 713, and a fourth adder 714, which are connected in sequence, and a fifth adder 715, a third PI controller 723, a sixth adder 716, a seventh adder 717, a fourth PI controller 724, and an eighth adder 718, which are connected in sequence.

The positive input of the first adder 711 is input U_crefNegative input terminal input U_cdThe output terminal of the first adder 711 is input to the first PI controller 721, and the output terminal of the first PI controller 721 is input to the second adder 712To the negative input of the second adder 712, and to the first positive input of the second adder U_cqω C, the signal output by the output of the second adder 712 is i_1drefThe signal is input to the positive input terminal of the third adder 713, and the negative input terminal of the third adder 713 is input to i_1dThe output terminal of the third adder 713 is input to the second PI controller 722, the output terminal of the second PI controller 722 is input to the first positive input terminal of the fourth adder 714, and the second positive input terminal of the fourth adder 714 is input to U_cdThe negative input terminal of the fourth adder 714 inputs i_1qωL₁The fourth adder 714 outputs electromotive force e_d。

The positive input end of the fifth adder 715 inputs 0, and the negative input end inputs U_cqThe output end of the fifth adder 715 is input to the third PI controller 723, the output end of the third PI controller 723 is input to the first positive input end of the sixth adder 716, and the second positive input end of the sixth adder 716 is input to U_cdω C, the signal output by the output terminal of the sixth adder 716 is i_1qrefThe signal is inputted to the positive input terminal of the seventh adder 717, and the negative input terminal of the seventh adder 717 is inputted to i_1qThe output terminal of the seventh adder 717 is input to the fourth PI controller 724, the output terminal of the fourth PI controller 724 is input to the first positive input terminal of the eighth adder 718, and the second positive input terminal of the eighth adder 718 is input to U_cqThe third positive input terminal of the eighth adder 718 is inputted i_1dωL₁The eighth adder 718 outputs electromotive force e_q。

U can be controlled by the dual-ring controller 700_cdNear target output voltage U_crefWhile U is_cqClose to 0.

FIG. 8 shows the input output current i₂The logic block diagram of the double-ring controller in the control device of the energy storage converter. The control parameters in the dual-loop controller 300 may be varied as required by the control strategy. In order to accelerate the response speed to the sudden change of the external load, the utility model discloses in, the output current i of energy storage converter has been introduced to the double-ring controller on the basis of fig. 7₂Is a new control parameter. As shown in fig. 8, the output current i to the storage converter₂Converting abc/dq coordinates to obtain i_2d、i_2q. The second adder 712 further includes a second positive input terminal, and the second positive input terminal of the second adder 712 is inputted with i_2d. The sixth adder 716 further comprises a third positive input terminal, and the third positive input terminal of the sixth adder 716 is inputted with i_2q。

"an embodiment," and/or "some embodiments" means a feature, structure, or characteristic described in connection with at least one embodiment of the application. Therefore, it is emphasized and should be appreciated that two or more references to "an embodiment" or "one embodiment" or "an alternative embodiment" in various places throughout this specification are not necessarily all referring to the same embodiment. Furthermore, some features, structures, or characteristics of one or more embodiments of the present application may be combined as appropriate.

Flow charts are used herein to illustrate operations performed by methods according to embodiments of the present application. It should be understood that the preceding operations are not necessarily performed in the exact order in which they are performed. Rather, various steps may be processed in reverse order or simultaneously. Meanwhile, other operations are added to or removed from these processes.

Although the present invention has been described with reference to the present specific embodiments, it will be understood by those skilled in the art that the above embodiments are merely illustrative of the present invention, and various equivalent changes and substitutions may be made without departing from the spirit of the present invention, and therefore, changes and modifications to the above embodiments within the spirit of the present invention will fall within the scope of the claims of the present application.

Claims (6)

1. A pre-synchronization device for converting off-grid to grid-connected of a microgrid based on multiple energy storage converters comprises a microgrid central controller, each energy storage converter comprises a direct-current power supply, a three-phase inverter circuit, a filter inductor and a filter capacitor which are sequentially connected, the filter capacitor is connected to a public bus of the microgrid through a transformer, each energy storage converter is connected with a local controller, the local controller of each energy storage converter is connected to the microgrid central controller,

the local controller cooperates with the microgrid central controller to adjust the voltage and the angular frequency of a microgrid bus by taking the angular frequency and the voltage of a large power grid as targets, cooperates with the microgrid central controller to adjust the phase of the microgrid bus by taking the phase of the large power grid as a target after the angular frequency deviation and the voltage deviation of the microgrid bus and the large power grid are smaller than preset values, and incorporates the microgrid into the large power grid after the angular frequency deviation, the voltage deviation and the phase deviation of the microgrid bus and the large power grid are smaller than the preset values.

2. The pre-synchronization apparatus of claim 1, wherein the local controller in cooperation with the microgrid central controller to adjust the voltage and the angular frequency of the microgrid bus to target the angular frequency and the voltage of the large power grid comprises: the microgrid central controller calculates the adjustment quantity of active power and reactive current according to the voltage and angular frequency of the microgrid common bus, and sends the adjustment quantity of the active power and the reactive current to the local controllers of the energy storage converters according to the distribution coefficients;

and each local controller adjusts the electromotive force e of the three-phase inverter circuit according to the distributed active power regulating quantity and reactive current regulating quantity until the deviation between the voltage and angular frequency of the microgrid public bus and the voltage and angular frequency of the large power grid is smaller than a preset value.

3. The pre-synchronization apparatus of claim 2, wherein the local controller comprises a droop controller and a dual-loop controller;

the droop controller outputs the target output voltage U of the energy storage converter according to the distributed reactive current regulation quantity_crefDroop control and target output angular frequency omega of energy storage converter according to distributed active power adjustment_refCarrying out droop control;

the dual-loop controller outputs current i according to the filter inductor₁Said lower partVoltage U of target output of droop controller_crefAnd target output angular frequency ω_refAnd generating a driving signal, and adjusting the electromotive force e of the three-phase inverter circuit by the energy storage converter according to the driving signal.

4. The presynchronization device of claim 2, wherein each of the local controllers adjusts the electromotive force e of the three-phase inverter circuit according to the distributed active power regulation amount and reactive current regulation amount from large to small according to the capacity of the corresponding energy storage converter.

5. The presynchronization device of claim 2, wherein the microgrid central controller calculates the adjustment amounts for active power and reactive current based on the voltage and angular frequency of the microgrid common bus using the formula:

ΔP_M＝(k_ω1+k_ω2/s)*(ω_G-ω_M)

ΔI_Q＝(k_u1+k_u2/s)*(U_G-U_M)

wherein, Δ P_MRepresenting the total regulation of active power, k_ω1Representing the proportionality coefficient, k, of a common bus frequency PI controller_ω2The/s represents the integral coefficient of the common bus frequency PI controller, omega_GRepresenting angular frequency, omega, of a large power network_MRepresenting angular frequency, Δ I, of a microgrid common bus_QRepresenting the total regulation of the reactive current, k_u1Representing the proportionality coefficient, k, of a common bus voltage PI controller_u2The/s represents the integral coefficient of the common bus voltage PI controller, U_GRepresenting the voltage, U, of a large power network_MAnd the voltage of the microgrid common bus is represented.

6. The pre-synchronization apparatus of claim 1, wherein the local controller, in cooperation with the microgrid central controller, adjusting the phase of the microgrid bus with the phase of the microgrid bus targeted at the phase of the microgrid comprises: to microgrid common bus voltage U_MCarrying out abc/dq conversion by taking the phase of a large power grid as reference to obtain U_MdAnd U_MqTarget 0 to U_MqAnd (6) carrying out adjustment.