CN111162562B - Coordinated fault ride-through method suitable for wind power MMC-MTDC system - Google Patents

Coordinated fault ride-through method suitable for wind power MMC-MTDC system Download PDF

Info

Publication number
CN111162562B
CN111162562B CN202010079516.5A CN202010079516A CN111162562B CN 111162562 B CN111162562 B CN 111162562B CN 202010079516 A CN202010079516 A CN 202010079516A CN 111162562 B CN111162562 B CN 111162562B
Authority
CN
China
Prior art keywords
wfmmc
power
formula
mmc
mtdc
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
CN202010079516.5A
Other languages
Chinese (zh)
Other versions
CN111162562A (en
Inventor
贾科
秦继朔
毕天姝
郑黎明
方煜
杨哲
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
North China Electric Power University
Original Assignee
North China Electric Power University
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by North China Electric Power University filed Critical North China Electric Power University
Priority to CN202010079516.5A priority Critical patent/CN111162562B/en
Publication of CN111162562A publication Critical patent/CN111162562A/en
Application granted granted Critical
Publication of CN111162562B publication Critical patent/CN111162562B/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Classifications

    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02JCIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
    • H02J3/00Circuit arrangements for ac mains or ac distribution networks
    • H02J3/36Arrangements for transfer of electric power between ac networks via a high-tension dc link
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E60/00Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02E60/60Arrangements for transfer of electric power between AC networks or generators via a high voltage DC link [HVCD]

Landscapes

  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Control Of Eletrric Generators (AREA)

Abstract

The invention discloses a coordinated fault ride-through method suitable for a wind power MMC-MTDC system, which comprises the steps of deducing coordinated fault ride-through control parameters based on a wind field side MMC converter WFMMC and a wind side VSC converter WVSC according to input and output power of each node of an MMC-MTDC; deducing a steady-state short-circuit current expression when a short-circuit fault occurs at an alternating current outlet of a receiving end converter GSMMC from a power angle according to the deduced coordinated fault ride-through control parameter; and finally, providing reference for selection of the specification of the submodule of the MMC converter and setting of protection of the alternating current side of the converter according to the deduced steady-state short-circuit current expression, so that coordinated fault ride-through of the wind power MMC-MTDC system is realized.

Description

Coordinated fault ride-through method suitable for wind power MMC-MTDC system
Technical Field
The invention relates to the field of power systems, in particular to a coordinated fault ride-through method suitable for a wind power MMC-MTDC system.
Background
The development and utilization of new energy represented by wind energy have important significance for social and economic development, environmental protection, coping with the current situation of energy shortage and the like. In recent years, great progress is made in development and utilization of wind power, and a large-scale wind power plant attracts wide attention through High Voltage Direct Current (HVDC) mode grid connection. The high-voltage direct-current transmission technology based on the Modular Multilevel Converter (MMC) combines a Voltage Source Converter (VSC) technology and a pulse width modulation technology, has the advantages of high modularization degree, good waveform quality, small occupied area and the like, and is an effective mode for large-scale wind power grid connection. Compared with an offshore wind farm, onshore wind energy resources are dispersed, and a multi-terminal wind power flexible direct-transmission system (MMC-MTDC) based on a direct-current transmission network is derived.
At present, the MMC-MTDC and wind field coordination low-pass research is less, fault passing is realized only through voltage reduction of a traditional wind field side MMC converter, unbalanced power during fault is not eliminated substantially, and the unbalanced power is transferred to the wind field side. This can make the fan bear great pressure back to back system, and Chopper circuit is frequently, the long-time is opened, may lead to the circuit to burn out, therefore it is necessary to study new wind-powered electricity generation MMC-MTDC system coordination fault through tactics. In addition, with the development of multi-terminal flexible direct current engineering represented by the north-tensioned flexible direct current transmission exemplary engineering, each node of the direct current transmission network is usually power-equivalent, that is, the possible input and output power of each node is considered in the planning process. On the basis, in order to provide reference for selection of the specification of the submodule of the MMC converter and setting of protection of the alternating current side of the converter, steady-state short-circuit current of each node when the alternating current side is in short circuit needs to be estimated in advance, so that a steady-state short-circuit current expression of the wind power MMC-MTDC system needs to be researched.
Disclosure of Invention
According to one aspect of the invention, a coordinated fault ride-through method suitable for a wind power MMC-MTDC system is provided, and the wind power MMC-MTDC system comprises: the system comprises an alternating current power grid, 3 wind power plants 1#, 2#, 3#, 1 GSMMC converter station, 3 WFMMC converter stations 1# WFMMC, 2# WFMMC and 3# WFMMC;
the alternating-current transmission voltage class of the alternating-current power grid is 220kV, the direct-current transmission voltage class is +/-500 kV, and the number of the MMC half-bridge sub-modules is 76;
in the wind fields of the 3 wind power plants 1#, 2#, 3#, the number of the permanent magnet fans is respectively 102, 92, 82, and the rated capacity of each fan is 5.2 MW; l01Is the length of the transmission line between 1# WFMMC and GSMMC02Is the length of the transmission line between 2# WFMMC and GSMMC13Is the length of the transmission line between 1# WFMMC and 3# WFMMC23Is the length of the transmission line between 2# WFMMC and 3# WFMMC01、l02、l13、l23Respectively 100km, 120km, 80km and 60 km; the coordinated fault ride-through method comprises the following steps:
step 1: deducing a coordinated fault ride-through control parameter based on a wind field side MMC converter WFMMC and a wind side VSC converter WVSC according to input and output power of each node of MMC-MTDC, specifically, when a short-circuit fault occurs at an alternating current outlet of a receiving end converter GSMMC, reducing alternating current input voltage of the WFMMC through WFMMC voltage reduction control, so that input power is reduced, and unbalanced power on a direct current transmission network is reduced; meanwhile, designing a wind turbine side VSC converter WTDSC step-down control coordinated with the WFMMC step-down control to eliminate unbalanced power;
WFMMC step-down control adopts V/f control mode, and the voltage amplitude and the frequency of control input transverter are the invariable value, WFMMC step-down control process includes:
during a fault, the ac voltage reference in the inverter control loop will be lowered, which is expressed as equation (1):
Figure GDA0003126677490000021
in the formula (I), the compound is shown in the specification,
Figure GDA0003126677490000022
is an alternating current voltage reference value, U 'in V/f control under normal working condition'ac_WFMMCReference value of AC voltage, U, redesigned for fault conditionsdcFor the MMC-MTDC direct voltage during a fault,
Figure GDA0003126677490000023
is a preset MMC-MTDC direct current upper limit value, KdcControlling parameters for WFMMC pressure reduction;
neglecting the active power loss of the MMC converter, the relation between the MMC-MTDC input and the output power during the fault is expressed as shown in an equation (2):
PS=PW-ΔP (2),
wherein, PSOutput power, P, for GSMMCWThe sum of input power of all WFMMCs is shown as delta P, and the difference between input power and output power of the MMC-MTDC is shown as delta P;
further expanding the formula (2) to be shown in the formula (3):
Figure GDA0003126677490000031
in the formula (3), I is the effective value of the alternating current input by WFMMC,
Figure GDA0003126677490000032
the value of the equivalent capacitance of the direct current transmission line is the sum of HBSM capacitance values of all sub modules on a bridge arm of the converter;
the formula (3) is further represented by the formula (4):
Figure GDA0003126677490000033
by integrating the formula (1) and the formula (4), the obtained value of the WFMMC pressure reduction control parameter is shown in the formula (5):
Figure GDA0003126677490000034
WVSC carries control down and adopts PQ control, guarantees that the active power and the reactive power of fan output are invariable, PQ control process includes: active power reference value P 'redesigned under fault condition'WTVSCExpressed by formula (6):
Figure GDA0003126677490000035
in the formula (I), the compound is shown in the specification,
Figure GDA0003126677490000036
is an active power reference value P 'in WVSC control under normal working condition'WTVSCActive power reference value, K, redesigned for fault conditionsPLoad reduction control parameters are provided for WVSC;
neglecting the active power loss of the MMC converter, the relation between the input power and the output power of the MMC-MTDC during the fault is shown as formula (2), and for each fan, the formula (2) is shown as formula (7):
Figure GDA0003126677490000037
in the formula, n is the sum of the number of fans connecting all the MMC-MTDC wind fields; delta P is the difference between input power and output power of the MMC-MTDC;
equation (7) is further written as shown in equation (8):
Figure GDA0003126677490000041
the value of the WTSC load reduction control parameter obtained by integrating the formula (6) and the formula (8) is shown as the formula (9),
Figure GDA0003126677490000042
step 2: according to the coordinated fault ride-through control parameter deduced in the step 1, deducing a steady-state short-circuit current expression when a short-circuit fault occurs at an alternating current outlet of a receiver converter GSMMC from a power angle; the process of deducing the steady-state short-circuit current expression when the short-circuit fault occurs at the alternating current outlet of the receiver converter GSMMC from the power angle comprises the following steps:
the power of the WFMMC input is expressed as shown in equation (10):
Figure GDA0003126677490000043
in the formula, PWFMMCAnd QWFMMCActive power and reactive power input by WFMMC respectively; u. ofWd、uWqD-axis voltage and q-axis voltage of the WFMMC alternating current side are respectively, and the values of the d-axis voltage and the q-axis voltage are determined by an alternating voltage reference value in WFMMC control; i.e. iWd、iWqThe values of d-axis and q-axis currents on the alternating side of WFMMC, which are determined by the power output from the wind field, are expressed by equation (11):
Figure GDA0003126677490000044
meanwhile, for the MMC-MTDC system, the relation between the input power and the output power is shown as the formula (12):
Figure GDA0003126677490000045
in the formula IdcIs the current of a DC transmission network, RdcIs a direct current transmission network resistor;
combining equations (10), (11), (12), and considering the setting of the MMC-MTDC transmission network topology, the GSMMC output active power is represented as equation (13):
Figure GDA0003126677490000046
in the formula, n1、n2、n3The number of 1#, 2#, 3# wind field fans, l01Is the length of the transmission line between 1# WFMMC and GSMMC02Is the length of the transmission line between 2# WFMMC and GSMMC13Is the length of the transmission line between 1# WFMMC and 3# WFMMC23Is the length of the transmission line between 2# WFMMC and 3# WFMMC, rdcThe resistance value of the direct current transmission line is a unit length;
for a symmetric short-circuit fault on the alternating current side of the GSMMC, the expression of the steady-state short-circuit current is shown as the formula (14):
Figure GDA0003126677490000051
for the asymmetric short-circuit fault on the alternating-current side of the GSMMC, the steady-state short-circuit current expression is shown as the following formula (15) due to the existence of negative sequence voltage and negative sequence current:
Figure GDA0003126677490000052
D1and D2The values are respectively shown in formula (16):
Figure GDA0003126677490000053
and step 3: and (3) providing reference for selection of the specification of the submodule of the MMC converter and setting of protection of the alternating current side of the converter according to the steady-state short-circuit current expression deduced in the step (2), so that coordinated fault ride-through of the wind power MMC-MTDC system is realized.
Drawings
FIG. 1 is a flow chart of a coordinated fault ride-through method applicable to a wind power MMC-MTDC system according to the present invention;
FIG. 2 is a wind power MMC-MTDC system topological diagram;
FIG. 3 is a permanent magnet wind turbine topology;
FIG. 4 is a block diagram of a voltage reduction control system for WFMMC during fault ride through;
FIG. 5 is a comparison graph of DC voltage waveforms of a conventional fault ride-through control system and a coordinated fault ride-through control system according to the present invention during a BC phase-to-phase short circuit fault;
FIG. 6 is a comparison graph of MMC-MTDC input and output active power waveforms during a BC phase-to-phase short circuit fault;
fig. 7 is a graph of input power and output power of a back-to-back system of a permanent magnet fan during a two-phase short circuit.
FIG. 8 is a graph of Chopper power consumption.
FIG. 9 is a comparison of simulated values and calculated values of steady-state short-circuit current under a three-phase short-circuit fault;
fig. 10 is a comparison of steady-state short-circuit current simulation values and calculated values under the BC-phase short-circuit fault.
Detailed Description
The present invention will be described in detail below with reference to the accompanying drawings.
FIG. 1 is a flowchart of a coordinated fault ride-through strategy and fault current analysis method of a wind power MMC-MTDC system according to the present invention. In this embodiment, a topological diagram of a wind power MMC-MTDC system to which the fault ride-through and fault current analysis method is applied is shown in fig. 2.
The wind power MMC-MTDC system comprises an alternating current power grid, 3 wind power plants, 1 GSMMC converter station and 3 WFMMC converter stations. The AC transmission voltage class of the AC power grid is 220kV, and the DC transmission voltage classThe voltage is +/-500 kV, the number of MMC half-bridge sub-modules is 76, the number of the permanent magnet fans in the wind fields of 1#, 2#, and 3# of the 3 wind power plants is respectively 102, 92, and 82, the rated capacity of a single fan is 5.2MW, and the length l of the direct current transmission line01、l02、l13、l23Respectively 100km, 120km, 80km and 60 km.
The permanent magnet fans in the three wind power plants of the invention mainly comprise fan mechanical parts and back-to-back systems with Chopper circuits, and the topological diagram is shown in fig. 3.
The method for coordinating fault ride-through and fault current analysis of the wind power MMC-MTDC system comprises the following steps of:
step 1: deducing a coordinated fault ride-through control parameter based on a wind field side MMC converter WFMMC and a wind side VSC converter WVSC according to input and output power of each node of the MMC-MTDC;
step 2: according to the coordinated fault ride-through control parameter deduced in the step 1, deducing a steady-state short-circuit current expression when a short-circuit fault occurs at an alternating current outlet of a receiver converter GSMMC from a power angle;
and step 3: and (3) providing reference for selection of the specification of the submodule of the MMC converter and setting of protection of the alternating current side of the converter according to the steady-state short-circuit current expression deduced in the step (2), so that coordinated fault ride-through of the wind power MMC-MTDC system is realized.
In the step 1, when a short-circuit fault occurs at an alternating current outlet of a receiving end converter (GSMMC), the output power of the GSMMC is sharply reduced, and the input power of the WFMMC is unchanged, which may cause a large amount of power accumulation on a direct current transmission network of the MMC-MTDC system, resulting in a rapid rise of the direct current voltage. The method adopted by the invention is to reduce the input power by reducing the alternating current input voltage of the WFMMC, thereby achieving the purpose of reducing the unbalanced power on the direct current transmission network.
The control mode adopted by the WFMMC is V/f control, namely the voltage amplitude and the frequency of the input converter are controlled to be constant values. During a fault, the AC voltage reference in the control loop of the converter is lowered, and the value thereof can be expressed as
Figure GDA0003126677490000071
In the formula (I), the compound is shown in the specification,
Figure GDA0003126677490000072
is an alternating current voltage reference value, U 'in V/f control under normal working condition'ac_WFMMCReference value of AC voltage, U, redesigned for fault conditionsdcFor the MMC-MTDC direct voltage during a fault,
Figure GDA0003126677490000073
is a preset MMC-MTDC direct current upper limit value, KdcThe value derivation process of the WFMMC pressure reduction control parameter is as follows.
Neglecting the MMC converter active power loss, the MMC-MTDC input and output power relation during the fault period can be expressed as
PS=PW-ΔP (2)
Wherein, PSOutput power, P, for GSMMCWΔ P is the MMC-MTDC input to output power difference for the sum of the input power of all WFMMCs.
The formula (2) can be further developed into
Figure GDA0003126677490000074
In the formula (3), I is the effective value of the alternating current input by WFMMC,
Figure GDA0003126677490000075
the value of the equivalent capacitance of the direct current transmission line is the sum of capacitance values of all sub modules (HBSM) on a bridge arm of the converter, and the increase of direct current voltage during a fault period is caused by the charging effect of the equivalent capacitance.
Formula (3) can be further written as
Figure GDA0003126677490000081
Comparing the formula (1) and the formula (4), it can be seen that the value of the pressure-reducing control parameter of WFMMC is
Figure GDA0003126677490000082
Because WFMMC step-down control is essentially to shift the unbalanced power of MMC-MTDC transmission network to the wind field and not to eliminate the unbalanced power, the wind machine side VSC converter (WTSCC) load reduction control which is coordinated with the WFMMC step-down control needs to be designed to eliminate the unbalanced power. The WTVVSC adopts PQ control to ensure that the active power and the reactive power output by the fan are constant, so that the load reduction control principle of the WTVVSC is to redesign the reference value of the active power, and the value can be expressed as
Figure GDA0003126677490000083
In the formula (I), the compound is shown in the specification,
Figure GDA0003126677490000084
is an active power reference value P 'in WVSC control under normal working condition'WTVSCActive power reference value, K, redesigned for fault conditionsPFor the load reduction control parameter of the WVSC, the derivation process is as follows.
Neglecting the active power loss of the MMC converter, the relation between the input power and the output power of the MMC-MTDC during the fault period is shown as the formula (2), and for each fan, the formula (2) can be written into the form of the formula (7).
Figure GDA0003126677490000085
In the formula, n is the sum of the number of fans connecting all the MMC-MTDC wind fields.
Formula (7) can be further written as
Figure GDA0003126677490000086
Comparing the formula (6) and the formula (8), it can be seen that the value of the WTSC load reduction control parameter is
Figure GDA0003126677490000087
In the step 2, the process of deducing the steady-state short-circuit current expression when the short-circuit fault occurs at the alternating current outlet of the receiving end converter (GSMMC) is as follows:
the power input by WFMMC can be expressed as
Figure GDA0003126677490000091
In the formula, PWFMMCAnd QWFMMCActive power and reactive power input by WFMMC respectively; u. ofWd、uWqD-axis voltage and q-axis voltage of the WFMMC alternating current side are respectively, and the values of the d-axis voltage and the q-axis voltage are determined by an alternating voltage reference value in WFMMC control; i.e. iWd、iWqThe d-axis current and the q-axis current on the alternating current side of the WFMMC respectively have values determined by the power output by a wind field and can be expressed as
Figure GDA0003126677490000092
Meanwhile, for the MMC-MTDC system, the relation between the input power and the output power is
Figure GDA0003126677490000093
In the formula IdcIs the current of a DC transmission network, RdcIs a direct current transmission network resistor.
Combining equations (10), (11), (12), and considering the MMC-MTDC transmission network topology adopted by the present invention, the GSMMC output power can be finally expressed as
Figure GDA0003126677490000094
In the formula, n1、n2、n3The number of 1#, 2#, 3# wind field fans, l01Is the length of the transmission line between 1# WFMMC and GSMMC02Is the length of the transmission line between 2# WFMMC and GSMMC13Is the length of the transmission line between 1# WFMMC and 3# WFMMC23Is the length of the transmission line between 2# WFMMC and 3# WFMMC, rdcIs the resistance value of the direct current transmission line with unit length.
For symmetric short-circuit fault on GSMMC AC side, the expression of steady-state short-circuit current is (14)
Figure GDA0003126677490000101
For the asymmetric short-circuit fault on the alternating current side of the GSMMC, the expression of the steady-state short-circuit current is shown as a formula (15) due to the existence of negative sequence voltage and negative sequence current
Figure GDA0003126677490000102
In the formula, D1And D2The values are respectively shown in formula (16),
Figure GDA0003126677490000103
it can be seen from the equations (13), (14) and (15) that after the short-circuit fault occurs on the ac side of the GSMMC, the steady-state short-circuit current is related to the length of each line of the MMC-MTDC dc transmission network, the number of wind field fans, the reference values of active power and reactive power of the fans, and the fault ride-through control system adopted by the whole system. It is noted that formula (13) does not have the WFMMC step-down control parameter KdcOnly the WTSCC load shedding control parameter K existsPThe steady-state short-circuit current output by the converter during the fault is not related to the voltage reduction degree of the WFMMC but related to the voltage reduction degree of the WTDCC.
FIG. 4 is a block diagram of a WFMMC buck control system during a fault. It should be noted that, since the configuration of the WTVSC load shedding control system is similar to the figure, the configuration of the WTVSC load shedding control system is not listed here.
Fig. 5 is a comparison graph of dc voltage waveforms for configuring a conventional fault ride-through system and for configuring a coordinated fault ride-through control system according to the present invention during a two-phase interphase short circuit fault. As is apparent from fig. 5, after 4.66 seconds of the fault, the dc voltage suppression effect of the coordinated fault ride-through method of the present invention is superior to that of the conventional fault ride-through method. The comparison graph proves the effectiveness of the wind power MMC-MTDC system coordination fault ride-through method provided by the invention.
Fig. 6 is a graph comparing MMC-MTDC input and output active power waveforms during a two-phase short circuit fault. As can be seen from the figure, the reduction of the MMC-MTDC input power is the root cause of the limitation of the dc voltage rise.
Fig. 7 is a graph of input power and output power of a back-to-back system of a permanent magnet fan during a two-phase short circuit. Under the influence of the fan load reduction control system, the input power of a back-to-back system of the fan is reduced along with the reduction of the output power during the fault, so that the unloading pressure of a Chopper circuit is reduced.
FIG. 8 is a graph of Chopper power consumption. As can be seen from the figure, the Chopper circuit under the traditional fault ride-through control has long switching-on time, high switching-on frequency and risk of burning; the on-time and the on-frequency of the Chopper circuit under the coordinated fault ride-through control are obviously reduced, and the strategy proves that the risk of burning the Chopper circuit can be effectively reduced.
Fig. 9 is a comparison of the simulated value and the calculated value of the steady-state short-circuit current under the three-phase short-circuit fault. The failure start time was 4.5s, the failure duration was 0.3s, and the transition resistance was 5 Ω. It can be seen from the figure that after about 10ms of fault, the A, B, C three-phase current simulated value waveform matches with the calculated value waveform, which proves that the steady-state short-circuit current expression provided by the invention is correct under the condition of symmetrical short-circuit fault.
Fig. 10 is a comparison of simulated and calculated steady-state short-circuit currents in a BC phase-to-phase short-circuit fault. The failure start time was 4.5s, the failure duration was 0.3s, and the transition resistance was 5 Ω. It can be seen from the figure that after about 17ms of fault, the A, B, C three-phase current simulation value waveform matches with the calculated value waveform, which proves that the steady-state short-circuit current expression provided by the invention is also correct under the condition of asymmetric short-circuit fault.
It should be noted that the above-mentioned embodiments are only preferred embodiments of the present invention, and should not be construed as limiting the scope of the present invention, and any minor changes and modifications to the present invention are within the scope of the present invention without departing from the spirit of the present invention.

Claims (1)

1. A coordinated fault ride-through method suitable for a wind power MMC-MTDC system, wherein the wind power MMC-MTDC system comprises: the system comprises an alternating current power grid, 3 wind power plants 1#, 2#, 3#, 1 GSMMC converter station, 3 WFMMC converter stations 1# WFMMC, 2# WFMMC and 3# WFMMC;
the alternating-current transmission voltage class of the alternating-current power grid is 220kV, the direct-current transmission voltage class is +/-500 kV, and the number of the MMC half-bridge sub-modules is 76;
in the wind fields of the 3 wind power plants 1#, 2#, 3#, the number of the permanent magnet fans is respectively 102, 92, 82, and the rated capacity of each fan is 5.2 MW; l01Is the length of the transmission line between 1# WFMMC and GSMMC02Is the length of the transmission line between 2# WFMMC and GSMMC13Is the length of the transmission line between 1# WFMMC and 3# WFMMC23Is the length of the transmission line between 2# WFMMC and 3# WFMMC01、l02、l13、l23Respectively 100km, 120km, 80km and 60 km; the coordinated fault ride-through method is characterized by comprising the following steps of:
step 1: deducing a coordinated fault ride-through control parameter based on a wind field side MMC converter WFMMC and a wind side VSC converter WVSC according to input and output power of each node of MMC-MTDC, specifically, when a short-circuit fault occurs at an alternating current outlet of a receiving end converter GSMMC, reducing alternating current input voltage of the WFMMC through WFMMC voltage reduction control, so that input power is reduced, and unbalanced power on a direct current transmission network is reduced; meanwhile, designing a wind turbine side VSC converter WTDSC step-down control coordinated with the WFMMC step-down control to eliminate unbalanced power;
WFMMC step-down control adopts V/f control mode, and the voltage amplitude and the frequency of control input transverter are the invariable value, WFMMC step-down control process includes:
during a fault, the ac voltage reference in the inverter control loop will be lowered, which is expressed as equation (1):
Figure FDA0003126677480000011
in the formula (I), the compound is shown in the specification,
Figure FDA0003126677480000012
is the AC voltage reference value in V/f control under normal working condition,
Figure FDA0003126677480000013
reference value of AC voltage, U, redesigned for fault conditionsdcFor the MMC-MTDC direct voltage during a fault,
Figure FDA0003126677480000014
is a preset MMC-MTDC direct current upper limit value, KdcControlling parameters for WFMMC pressure reduction;
neglecting the active power loss of the MMC converter, the relation between the MMC-MTDC input and the output power during the fault is expressed as shown in an equation (2):
PS=PW-ΔP (2),
wherein, PSOutput power, P, for GSMMCWThe sum of input power of all WFMMCs is shown as delta P, and the difference between input power and output power of the MMC-MTDC is shown as delta P;
further expanding the formula (2) to be shown in the formula (3):
Figure FDA0003126677480000021
in the formula (3), I is the effective value of the alternating current input by WFMMC,
Figure FDA0003126677480000022
the value of the equivalent capacitance of the direct current transmission line is the sum of HBSM capacitance values of all sub modules on a bridge arm of the converter;
the formula (3) is further represented by the formula (4):
Figure FDA0003126677480000023
by integrating the formula (1) and the formula (4), the obtained value of the WFMMC pressure reduction control parameter is shown in the formula (5):
Figure FDA0003126677480000024
WVSC carries control down and adopts PQ control, guarantees that the active power and the reactive power of fan output are invariable, PQ control process includes: active power reference value P 'redesigned under fault condition'WTVSCExpressed by formula (6):
Figure FDA0003126677480000025
in the formula (I), the compound is shown in the specification,
Figure FDA0003126677480000026
is an active power reference value P 'in WVSC control under normal working condition'WTVSCActive power reference value, K, redesigned for fault conditionsPLoad reduction control parameters are provided for WVSC;
neglecting the active power loss of the MMC converter, the relation between the input power and the output power of the MMC-MTDC during the fault is shown as formula (2), and for each fan, the formula (2) is shown as formula (7):
Figure FDA0003126677480000027
in the formula, n is the sum of the number of fans connecting all the MMC-MTDC wind fields; delta P is the difference between input power and output power of the MMC-MTDC;
equation (7) is further written as shown in equation (8):
Figure FDA0003126677480000028
the value of the WTSC load reduction control parameter obtained by integrating the formula (6) and the formula (8) is shown as the formula (9),
Figure FDA0003126677480000031
step 2: according to the coordinated fault ride-through control parameter deduced in the step 1, deducing a steady-state short-circuit current expression when a short-circuit fault occurs at an alternating current outlet of a receiver converter GSMMC from a power angle; the process of deducing the steady-state short-circuit current expression when the short-circuit fault occurs at the alternating current outlet of the receiver converter GSMMC from the power angle comprises the following steps:
the power of the WFMMC input is expressed as shown in equation (10):
Figure FDA0003126677480000032
in the formula, PWFMMCAnd QWFMMCActive power and reactive power input by WFMMC respectively; u. ofWd、uWqD-axis voltage and q-axis voltage of the WFMMC alternating current side are respectively, and the values of the d-axis voltage and the q-axis voltage are determined by an alternating voltage reference value in WFMMC control; i.e. iWd、iWqThe values of d-axis and q-axis currents on the alternating side of WFMMC, which are determined by the power output from the wind field, are expressed by equation (11):
Figure FDA0003126677480000033
meanwhile, for the MMC-MTDC system, the relation between the input power and the output power is shown as the formula (12):
Figure FDA0003126677480000034
in the formula IdcIs the current of a DC transmission network, RdcIs a direct current transmission network resistor;
combining equations (10), (11), (12), and considering the setting of the MMC-MTDC transmission network topology, the GSMMC output active power is represented as equation (13):
Figure FDA0003126677480000035
in the formula, n1、n2、n3The number of 1#, 2#, 3# wind field fans, l01Is the length of the transmission line between 1# WFMMC and GSMMC02Is the length of the transmission line between 2# WFMMC and GSMMC13Is the length of the transmission line between 1# WFMMC and 3# WFMMC23Is the length of the transmission line between 2# WFMMC and 3# WFMMC, rdcThe resistance value of the direct current transmission line is a unit length;
for a symmetric short-circuit fault on the alternating current side of the GSMMC, the expression of the steady-state short-circuit current is shown as the formula (14):
Figure FDA0003126677480000041
for the asymmetric short-circuit fault on the alternating-current side of the GSMMC, the steady-state short-circuit current expression is shown as the following formula (15) due to the existence of negative sequence voltage and negative sequence current:
Figure FDA0003126677480000042
D1and D2The values are respectively shown in formula (16):
Figure FDA0003126677480000043
and step 3: and (3) providing reference for selection of the specification of the submodule of the MMC converter and setting of protection of the alternating current side of the converter according to the steady-state short-circuit current expression deduced in the step (2), so that coordinated fault ride-through of the wind power MMC-MTDC system is realized.
CN202010079516.5A 2020-02-04 2020-02-04 Coordinated fault ride-through method suitable for wind power MMC-MTDC system Active CN111162562B (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202010079516.5A CN111162562B (en) 2020-02-04 2020-02-04 Coordinated fault ride-through method suitable for wind power MMC-MTDC system

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202010079516.5A CN111162562B (en) 2020-02-04 2020-02-04 Coordinated fault ride-through method suitable for wind power MMC-MTDC system

Publications (2)

Publication Number Publication Date
CN111162562A CN111162562A (en) 2020-05-15
CN111162562B true CN111162562B (en) 2021-11-02

Family

ID=70565200

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202010079516.5A Active CN111162562B (en) 2020-02-04 2020-02-04 Coordinated fault ride-through method suitable for wind power MMC-MTDC system

Country Status (1)

Country Link
CN (1) CN111162562B (en)

Families Citing this family (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN114035111B (en) * 2021-11-05 2023-05-19 广东电网有限责任公司 Short-circuit current measuring method and device for soft-direct near-end alternating-current bus
CN114552625B (en) * 2022-04-26 2022-07-19 华北电力大学(保定) Hybrid ride-through method for direct-current short-circuit fault of MMC-MTDC system

Family Cites Families (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP2606548B1 (en) * 2010-08-18 2015-09-23 Vestas Wind Systems A/S Method of controlling a grid side converter of a wind turbine and system suitable therefore
CN103825267B (en) * 2014-03-07 2015-08-26 浙江大学 A kind of computational methods of MMC-MTDC dc-side short-circuit electric current
CN106099968A (en) * 2016-08-05 2016-11-09 西安许继电力电子技术有限公司 Marine wind electric field DC transmission system DC short trouble traversing method and system
CN108539796B (en) * 2018-05-31 2023-08-25 华中科技大学 Fault ride-through and energy dissipation control method for wind power bipolar flexible direct current power grid
CN109347144B (en) * 2018-11-21 2022-05-17 华北电力大学 Low voltage ride through method of wind power flexible direct current output system
CN110108921B (en) * 2019-05-27 2020-04-07 山东大学 Flexible direct-current power grid short-circuit current calculation method and system considering converter control

Also Published As

Publication number Publication date
CN111162562A (en) 2020-05-15

Similar Documents

Publication Publication Date Title
Xu et al. Multi-terminal DC transmission systems for connecting large offshore wind farms
CN109347144B (en) Low voltage ride through method of wind power flexible direct current output system
Reddy et al. Design of RBFN controller based boost type Vienna rectifier for grid-tied wind energy conversion system
CN107863780B (en) Fault control method and device for offshore wind power direct current sending-out system
CN113972682B (en) Voltage control method and device for direct current bus and power system
Farantatos et al. Short-circuit current contribution of converter interfaced wind turbines and the impact on system protection
CN114825431B (en) Grid-connected system and control and protection system for sending wind power plant out through diode rectification
CN111162562B (en) Coordinated fault ride-through method suitable for wind power MMC-MTDC system
CN113949089A (en) Electrochemical energy storage commutation system and method with harmonic suppression capability
CN114172203A (en) Control method for parallel power supply system of generator-network type MMC converter station
CN105633998A (en) Wind generating set high-voltage crossing control method and device
CN105633999A (en) High-voltage crossing control method and device under imbalanced sudden rise of power grid voltage
CN106469915A (en) A kind of photovoltaic combining inverter self adaptation dynamic reactive compensating method
CN104734537A (en) Control method for wind power current converter based on positive-and-negative sequence current inner-loop control
Hassanzadeh et al. Back-to-back converter control of grid-connected wind turbine to mitigate voltage drop caused by faults
Andrade et al. Distributed control strategy for a wind generation systems based on PMSG with uncontrolled rectifier HVDC connection
Abir et al. Control of permanent-magnet generators applied to variable-speed wind-energy
CN111756066A (en) Operation control and island detection method and system for photovoltaic direct current converter
Mrčela et al. A wind turbine two level back-to-back converter power loss study
CN115622110A (en) Offshore wind power flexible direct current grid-connected system and control method thereof
Belabbas et al. A hierarchical control scheme to improve the stability and energy quality of a hybrid wind/photovoltaic system connected to the electricity grid
CN111478366B (en) Double-fed fan low-voltage ride-through control method and system based on transient overvoltage suppression
Subburaj et al. Battery and wind system in weak/strong grid analysis
De Kooning et al. Joule losses and torque ripple caused by current waveforms in small and medium wind turbines
Torres-Olguin et al. Grid Integration of offshore wind farms using a Hybrid HVDC composed by an MMC with an LCC-based transmission system

Legal Events

Date Code Title Description
PB01 Publication
PB01 Publication
SE01 Entry into force of request for substantive examination
SE01 Entry into force of request for substantive examination
GR01 Patent grant
GR01 Patent grant