The present invention relates to fault-tolerant control for a multi-level inverter in power electronics, and relates in particular to a voltage reference reconfiguration fault-tolerant control method for a multi-level inverter.
Recent years have seen rapid promotion and application of high-voltage high-power converters in industrial manufacturing and transportation, thanks to their excellent properties and energy saving effectiveness. On the other hand, voltage withstand capacity of switching devices has severely constrained development of high voltage frequency conversion techniques. To obtain higher output voltage on the basis of current level of switching devices, multi-level inverters find wide applications in industrial manufacturing, transportation, and aerospace, owing to their high quality of output power, low voltage stress, and low switching loss. Topologies of a multi-level inverter mainly include diode-clamped, flying capacitor, or cascaded multi-level inverters. Among them, a bridge multi-level inverter finds wide application in industry as it can do without a large number of clamped diodes and capacitors, has no need for balanced capacitance and voltage, and has an easily modularized and expandable structure with good power quality.
However, an H-bridge multi-level inverter employed in actual industrial process contains a large number of H-bridges in each phase, which greatly increases the occurrence of open or short circuits for the switching devices. Further, with the increase of voltage, fault occurrence probability increases. An H-bridge multi-level inverter indeed provides convenience for applying electrical and electronic techniques in high voltage and large power applications, but once a fault takes place, a small one might cause factory shut down, while a severe one might result in catastrophic incidents and huge societal loss. Research indicates that switching device faults account for 82.5% of faults of the whole drive system in an inverter-powered variable frequency speed regulation system, and thus a switching device is the most vulnerable sector in the drive system.
Currently, there are two fault-tolerant strategies for countering inverter open circuit IGBT faults. One of the strategies is the hardware redundant method of adding redundant bridges or redundant modules. Such a method may operate with full load, but is at the cost of increase of cost, inverter weight, and complexity. In situations where volume and weight are strictly restricted, such a method is not adoptable. The other strategy taking reduction of manufacturing cost into account is to make use of the available switching devices and to operate under reduced load, wherein fault-tolerant objective is achieved by means of altering the control algorithm. Traditional multi-level inverter PWM waveform modulation algorithm is unable to adapt to inverter control subsequent to removal of fault modules, requiring a substitute thereof for fault controlling. The higher level of the inverter, the more pieces of redundant algorithm are required to be added in. Moreover, algorithm switching requires fault diagnosis and algorithm selection. In a high level multi-level inverter, fault types are numerous, time for overall algorithm selection is long, and thus system response time is extended.
The present invention is the first in incorporating fault signals in multi-level inverter PWM waveform configuration under fault condition, wherein fault bridges are removed and normal bridges are fault-controlled by means of reconfiguration of total reference voltage amplitude, phase, and reconfiguration of reference voltage of the various H-bridges.
The object of the present invention is to provide a reference voltage reconfiguration fault-tolerant control method for fault control of a multi-level inverter, with the technical solution as follows:
A voltage reference reconfiguration fault-tolerant control method for a multi-level inverter is disclosed, wherein the inverter comprises a plurality of DC power sources, an H-bridge circuit, a fault diagnosis module, a PWM waveform generating module, and a resistor. The PWM waveform generating module generates a switching signal for driving the H-bridge circuit in converting DC from the DC power source into AC. Voltage of the AC is measured for a fault diagnosis, with an outcome of the fault diagnosis being employed for reconfiguring a PWM waveform in fault-controlling the inverter. The fault diagnosis is driven, wherein three-phase voltage signals corresponding to each type of fault under normal and fault conditions respectively are sampled for signal preprocessing with fast Fourier transform (FFT), principal component extraction by principal component analysis (PCA), and back propagation (BP) neural network training to obtain a BP neural network weight matrix, called pre-set weight matrix. The fault features of many signals are not obvious in the time domain, but they are obvious in the frequency domain. Therefore, the signals in the time domain are often converted to the frequency domain by Fourier transform to achieve the purpose of fault feature extraction. PCA algorithm is adopted for dimensionality reduction processing of data to speed up the training of neural networks. In a real-time system, three-phase voltage signals are sampled for FFT, PCA principal component extraction, and are combined with the pre-set weight matrix for fault diagnosis.
Each phase of a main circuit of the cascaded multi-level inverter is comprised of n H-bridges. Each H-bridge comprises a plurality of IGBTs, wherein n is an integer greater than or equal to two. A triac as an isolation switch is installed between a left arm and a right arm of each H-bridge for isolation of a faulty H-bridge in case of occurrence of a fault in the faulty H-bridge. The carrier disposition SPWM modulation algorithm is selected as the principle PWM waveform modulation algorithm.
For the H-bridge circuit, all the IGBTs open circuit faults are categorized as one type. That is, no matter how many faults occur for the fault IGBT bridges, they are regarded as an H-bridge fault. The present invention is thus more suited for fault-tolerant control of the H-bridges.
Real-time detection and fault diagnosis of the output voltage of the inverter is carried out via the fault diagnosis module. Amplitude and phase of the three-phase total reference voltage are then configured according to the outcome of the diagnosis, with a fault signal vector being set up for reconfiguration of the reference voltage signal of each H-bridge and fault-tolerant control being conducted for the H-bridge multi-level inverter utilizing the reconfigured PWM waveform.
is as follows:
Step 1, pre-setting a three-phase fault signal vector:
letting λAi i=1, 2, 3, . . . n, be a fault signal for an ith H-bridge in an A-phase, with λAi=0 representing occurrence of no fault in the ith H-bridge, λAi=1 representing occurrence of the fault in the ith H-bridge, uAref+(t) standing for a reference voltage of a PWM waveform generated in comparison with a triangular waveform of a left arm in the ith H-bridge in the A-phase, and uAref−(t) standing for a reference voltage of a PWM waveform generated in comparison with a triangular waveform of a right arm in the ith H-bridge in the A-phase and uAref(t) standing for a reference voltage of a PWM waveform generated in comparison with a triangular waveform in the ith H-bridge in the A-phase; letting λBi i=1, 2, 3, . . . n, be a fault signal for an ith H-bridge in a B phase, λBi=0 representing occurrence of no fault in the ith H-bridge, λBi=1 representing occurrence of a fault in the ith H-bridge; uBref+(t) standing for a reference voltage of a PWM waveform generated in comparison with a triangular waveform of a left arm in the ith H-bridge in the B-phase, and uBref−(t) standing for a reference voltage of a PWM waveform generated in comparison with a triangular waveform of a right arm in the ith H-bridge in the B-phase and uBref(t) standing for a reference voltage of a PWM waveform generated in comparison with a triangular waveform in the ith H-bridge in the B-phase; letting λCi i=1, 2, 3, . . . n, be a fault signal for an ith H-bridge in a C phase, with λCi=0 representing occurrence of no fault in the ith H-bridge, λCi=1 representing occurrence of a fault in the ith H-bridge; uCref+(t) standing for a reference voltage of a PWM waveform generated in comparison with a triangular waveform of a left arm in the ith H-bridge in the C-phase, and uCref−(t) standing for a reference voltage of a PWM waveform generated in comparison with a triangular waveform of a right arm in the ith H-bridge in the C-phase and uCref(t) standing for a reference voltage of a PWM waveform generated in comparison with a triangular waveform in the ith H-bridge in the C-phase;
For a three-phase voltage under normal operation, fault signal for each H-bridge is 0, and thus reference voltages are as follows:
Setting the three-phase fault signal vector as:
Step 2, pre-setting three-phase reference voltage amplitude coefficients
Let p, q, r be a number of healthy bridges respectively in phases A, B, and C. Reconfiguration of reference voltage amplitude coefficients:
When p=q=r, let p*=q*=r*=p=q=r,
wherein, θAB, θBC, θAC are respectively the phase differences between phases A and B, between B and C, and between A and C, and p*, q*, r* are respectively the reference voltage amplitude coefficients for phases A, B, and C.
Step 3, removing each faulty H-bridge by means of the respective isolation switch:
Obtaining fault locations and numbers thereof for all the IGBTs, and closing the isolation of each respective H-bridge where a faulty IGBT is located, thereby removing the fault H-bridge from the inverter.
Step 4, reconfiguring total phase voltages for the three phases:
When A-phase has the most numerous normal bridges, and for p<q+r, then θAB, θBC, θAC, p*, q*, and r* are configuring in accordance with expression (1):
for p≥q+r, then θAB, θBC, θAC, p*, q*, and r* are configuring in accordance with expression (2):
When B-phase has the most numerous normal bridges,
for q<p+r, then θAB, θBC, θAC, p*, q*, and r* are configuring in accordance with expression (3):
for q≥p+r, then θAB, θBC, θAC, p*, q*, and r* are configuring in accordance with expression (4):
When C-phase has the most numerous normal bridges,
for r<p+q, then θAB, θBC, θAC, p*, q*, and r* are configuring in accordance with expression (5):
for r≥p+q, then θAB, θBC, θAC, p*, q*, and r* are reconfigured in accordance with expression (6):
Thus the reference voltage amplitude coefficients and the phase differences of the three phases under various conditions are obtained via the above calculations.
Conducting fault bridge removal and reference voltage reconfiguration for the healthy bridges as follows:
Update the fault signal vectors A, B, and C according to the fault locations and the numbers thereof for all the IGBTs. Calculate remaining normal bridges for each said phase according to expression (7).
Reconfigure the total phase voltages for the three phases by means of selecting the corresponding reference voltage amplitude coefficients and reconfigured phase values calculated in accordance with the p, q, and r values:
Step 5 reconfiguring the remaining normal bridges
Reconfiguring the reference voltage signal for the fault bridge in combination with the expression (9),
By means of the afore-mentioned re-reconfiguration of the on-line reference voltage signal, removal of the fault bridges for the cascaded H-bridge multi-level inverter under non-redundant algorithm is realized, enabling the cascaded H-bridge multi-level inverter to operate under reduced voltage level and balanced three phase voltages.
The present invention is advantageous in that:
1. The present invention reconfigures the three-phase voltage amplitudes and phases in accordance with the fault diagnosis, thus realizing three-phase voltage balance.
2. The present invention re-reconfigures the reference voltage signal for the fault bridges to realize zero voltage on both ends of the bypass circuit breaker, thereby eliminating possible security hazards.
3. The present invention re-reconfigures the reference voltage signals for the normal bridges to realize voltage transmission among bridges, thus achieving fault-tolerant objective.
4. The present invention adopts the same PWM waveform modulation method for the inverter both under normal and fault conditions, and thereby has no algorithm redundancy or increased complexity for the control program, thus reducing controller fault likelihood.
The present invention will be expounded in more details with the figures and an embodiment hereunder provided.
As is shown in
The H-bridge seven-level inverter consists of three single-phase H-bridge structures as are shown in
The fault diagnosis module of the inverter adopts a fault diagnosis method based on data driving. Three-phase voltage samples are first collected respectively for normal and fault situations in accordance with the types of the faults. FFT, PCA principal component extraction, and BP neural network data pre-processing are then conducted for the samples to obtain a BP neural network weight matrix. And finally in the real-time system, FFT, PCA principal component extraction are conducted for the three-phase voltage samples in combination with the pre-set weight matrix for conducting fault diagnosis.
The specific fault-tolerant method is as follows:
Step 1, pre-setting a three-phase fault signal vectors: In a seven-level inverter, let the fault signal vectors of the phases A, B, and C respectively be A, B, and C, wherein λA1, λA2, and λA3 are respectively the fault signals of the first, second, and third bridges of phase A. Alternatively, λB1, λB2, λB3, λC1, λC2, λC3 are respectively the fault signals of the first, second, and third bridges of phases B and C. The fault signal vectors may then be set up as:
Step 2, pre-setting three-phase reference voltage amplitude coefficients and phase reconfiguration: Let p, q, r be a number of healthy bridges respectively in phases A, B, and C. Reconfiguration of reference voltage amplitude coefficients and phase differences of the three phases in accordance with fault conditions is conducted as follows:
When p=q=r, let p*=q*=r*=q=r,
wherein θAB, θBC, θAC are respectively the phase differences between phases A and B, between B and C, and between A and C, and p*, q*, r* are respectively the reference voltage amplitude coefficients for phases A, B, and C.
Step 3, removing each faulty H-bridge by means of the respective isolation switch:
Obtaining fault locations and numbers thereof for all the IGBTs, and closing the isolation switch of each respective H-bridge where a faulty IGBT is located, thereby removing the fault H-bridge from the inverter.
Step 4, reconfiguring total phase voltages for the three phases:
When A-phase has the most numerous normal bridges, and for p<q+r, then θAB, θBC, θAC, p*, q*, and r* are configuring in accordance with expression (1):
for p≥q+r, then θAB, θBC, θAC, p*, q*, and r* are configuring in accordance with expression (2):
When B-phase has the most numerous normal bridges,
for q<p+r then θAB, θBC, θAC, p*, q*, and r* are configuring in accordance with expression (3):
for q≥p+r, then θAB, θBC, θAC, p*, q*, and r* are configuring in accordance with expression (4):
When C-phase has the most numerous normal bridges,
for r<p+q, then θAB, θBC, θAC, p*, q*, and r* are configuring in accordance with expression (5):
for r≥p+q, then θAB, θBC, θAC, p*, and r* are configuring in accordance with expression (6):
According to the afore-mentioned expressions (1)-(6), reconfigured values of the three-phase reference phase voltage amplitude coefficients and phase differences may be calculated in accordance with their corresponding fault types of the cascaded H-bridge inverter.
Conducting fault bridge removal and reference voltage reconfiguration for the healthy bridges as follows:
update the fault signal vectors A, B, and C according to the fault locations and the numbers thereof for all the IGBTs. Calculate the remaining normal bridges for each said phase according to expression (7).
Reconfigure the total phase voltages for the three phases by means of selecting the corresponding reference voltage amplitude coefficients and reconfigured phase values calculated in off-line setting in accordance with the p, q, and r values calculated in on-line setting:
Step 5 reconfiguring the remaining normal bridges:
reconfigure the reference voltage signal for the fault bridge in combination with the expression (9).
The reconfiguration method of the present invent is mainly based on task relay in-between the bridges, wherein a voltage output task for a fault bridge is relayed to a normal H-bridge in a layer there-above, while a voltage output task for a normal bridge is relayed to another normal H-bridge in a layer further above, and so on, such that total voltage output is realized subsequent to total voltage amplitude reconfiguration; as is shown in
Via the afore-mentioned steps, fault-tolerant control of single and multiple faults of the seven-level inverter is realized, while keeping the three-phase line voltage in balance at the mean time. After the faults are removed, by just setting all the fault signals to 0, the inverter will resume normal operation.
The basic principles and chief characteristics, as well as the advantages of the present invention have thus been described. A person of the art shall understand that the present invention is not limited to the afore-described embodiment, that the embodiment and the accompanying description only serve to delineate the principles of the present invention, and that various modifications and improvements without departure from the spirit and scope of the present invention shall fall within the scope of protection of the present invention. The scope of protection as requested by the present invention is defined by the accompanying Claims and the equivalents thereof.
Number | Date | Country | Kind |
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2016 1 0297592 | May 2016 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2016/103751 | 10/28/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/190480 | 11/9/2017 | WO | A |
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