Microsoft Word - 5-777-ed.doc Engineering, Technology & Applied Science Research Vol. 6, No. 5, 2016, 1133-1138 1133 www.etasr.com Demirdelen et al.: A Modular Cascaded Multilevel Inverter Based Shunt Hybrid Active Power Filter… A Modular Cascaded Multilevel Inverter Based Shunt Hybrid Active Power Filter for Selective Harmonic and Reactive Power Compensation Under Distorted/Unbalanced Grid Voltage Conditions T. Demirdelen Cukurova University, Department of Electrical and Electronics Engineering, Balcali, Adana, Turkey tdemirdelen@cu.edu.tr R. I. Kayaalp Cukurova University, Department of Electrical and Electronics Engineering, Balcali, Adana, Turkey ikayaalp@cu.edu.tr M. Tumay Cukurova University, Department of Electrical and Electronics Engineering, Balcali, Adana, Turkey mtumay@cu.edu.tr Abstract—In recent years, shunt hybrid active power filters are being increasingly considered as a viable alternative to both passive filters and active power filters for compensating harmonics. In literature, their applications are restricted to balanced systems and low voltage applications and therefore not for industrial applications. This paper investigates the performance of a modular cascaded multilevel inverter based Shunt Hybrid Active Power Filter (SHAPF) for reactive power compensation and selective harmonics elimination under distorted/unbalanced grid voltage conditions in medium voltage levels. In the proposed control method, reactive power compensation is achieved successfully with a perceptible amount and the performance results of harmonic compensation are satisfactory. Theoretical analysis and simulation results are obtained from an actual industrial network model in PSCAD. The simulation results are presented for a proposed system in order to demonstrate that the harmonic compensation performance meets the IEEE-519 standard. Keywords-harmonic compensation; medium voltage applications; modular cascaded multilevel inverter; reactive power compensation; shunt hybrid active power filter I. INTRODUCTION In recent years, high power equipment has been employed in industrial applications due to the megawatt power level for many medium voltage applications. Due to this condition, multilevel power converters are to be used as an alternative solution in medium and high voltage applications. Multilevel converters have the ability to increase the output voltage without raising the voltage rating of switching components. Thus, they are preferred to connect to medium voltage grids without using transformers. Among the various multilevel converters topologies, cascaded inverters consist of several converters connected in series. Thus, the high power and/or high voltage from the combination of the multiple modules would favor this topology in medium and high voltage applications. The modular multilevel inverter has been used as an alternative choice to conventional multilevel inverters. It has been designed to mitigate the drawbacks of conventional multilevel inverters such as the difficulty of balancing the capacitor voltage on higher order levels, the need for an output filter and interfacing transformer. Also conventional multilevel inverters are not capable of fault management and fault ride through. The modular cascaded H-bridge multilevel inverter is one of the cascaded inverter topologies. The output multilevel voltage waveforms enable the reduction of harmonics in the synthesized current, reducing the size of the needed output filters. The cascaded multilevel inverter also has other advantages such as reduced voltage stresses on the semiconductor switches, as well as having higher efficiency when compared to other converter topologies [1]. Using identical power cells leads to a modular structure, which is an effective means for cost reduction. The aforementioned reasons caused to compose the modular cascaded multilevel inverter based SHAPF investigated in this paper. The increase of nonlinear loads causes several power quality problems in power systems. The grid voltage and currents become non sinusoidal due to these types of loads. The traditional yet ineffective solution to reduce current harmonic distortion is passive filters. Active power filters have become a new research emphasis on power electronics technology as a new and improved solution to the problem. Hybrid active power filters effectively smooth the problems of passive filters and an active power filter solution may ensure a cost effective harmonic compensation. Several hybrid APF (HAPF) topologies are introduced in [2-10, 13] for reactive power and harmonic current filtering. The most common topologies are shunt HAPF (SHAPF) [4-12] consisting of an APF and a passive filter connected in series with each other and series HAPF [3] which is a combined system of the shunt passive filter and a series APF. An extensive overview of the topological structures is given in [2, Engineering, Technology & Applied Science Research Vol. 6, No. 5, 2016, 1133-1138 1134 www.etasr.com Demirdelen et al.: A Modular Cascaded Multilevel Inverter Based Shunt Hybrid Active Power Filter… 13]. Most articles describe research focused on low voltage levels. On the contrary, Multilevel SHAPF (M-SHAPF) [6-7, 11-12] is the most often used in medium voltage levels in industrial applications. The controller design is the most important part due to its impact on the performance and stability of the overall system. For this reason, numerous control methods such as pq theory [4], dq theory [5-7, 12], fuzzy controller [8] etc… have been applied for the harmonic compensation in the literature. In literature, shunt hybrid active power filters [2-5, 8-10] are restricted to balanced systems and low voltage applications and thus cannot be employed for industrial applications. On account of the limitations between existing literatures, the purpose of this paper is the following: 1. To investigate the performance of the modular cascaded multilevel inverter based shunt hybrid active power filter for reactive power compensation and selective harmonics elimination under distorted/unbalanced grid voltage conditions. 2. To investigate the application of this control method in medium voltage levels. 3. To perform theoretical analysis and simulation results for an actual industrial network model in PSCAD. 4. To check the compliance of the results with the IEEE- 519 standard. 5. To apply dynamic load changes and observe the system response. II. PROPOSED SYSTEM AND CONTROLLER Figure 1 shows the detailed circuit configuration of the proposed system. As shown, a modular cascaded multilevel inverter unit is connected to the grid through a LC filter tuned on the vicinity of the 5th harmonic. As shown in Figure 2, the controller of the proposed system consists of six main parts: phase lock loop, harmonic reference generation, reactive current reference generation, selective harmonic reference generation, dc link voltage controller and final reference compensation current- pwm control block. A. Differential Phase Lock Loop The phase angle (θ) of the supply voltage is required which affects the performance of the control method. Hence, an accurate phase tracking system is the key point of the control method to transform the measured current vectors into synchronously rotating d-q reference frame. Thus, Dif-PLL is selected for extracting the phase angle (θ) [14] shown in Figure 2 (a). B. Harmonic Reference Generation The first step of harmonic current control is to isolate the harmonic components from the fundamental component of the grid currents. This is achieved through the dq transformation (2), synchronized with the PCC voltage vector, and a first order low pass filter (LPF) with cut off frequency of 10 Hz. Then the dq inverse transformation (4) produces the harmonic currents in the abc referential frame shown in Figure 2 (b). The conversion matrix is: )1( 2 2 2 2 2 2 ) 3 2sin() 3 2sin(sin ) 3 2cos() 3 2cos(cos 3 2123                      ppp ppp dqT )2(123                      Sc Sb Sa dq o q d i i i T i i i and the inverse conversion matrix is: )3( 2 2 ) 3 2sin() 3 2cos( 2 2 ) 3 2sin() 3 2cos( 2 2 sincos 3 2 123                          pp pp pp dqT )4( _ _ _ 123 __ __ __                      lpfo lpfq lpfd dq refharmonicc refharmonicb refharmonica i i i T i i i C. Reactive Current Reference Generation The reference current provided the essential reactive power is produced. In order to achieve the reactive power compensation of M-SHAPF, the reference current having 90o phase difference among the PCC point should be produced. To produce this reference current, the output voltage of M-SHAPF inverter should be generated in the phase with PCC voltage vector. The block diagram of reactive power control is shown in Figure 2(c). )5(123                      sc sb sa dq o q d i i i T i i i )6( 0 0 _ 123 __ __ __                      fundq dq refreactivec refreactiveb refreactivea i T i i i For the realization of the reactive power compensation, the reference currents should be calculated. The reference currents are generated by the dq method. The first step is to isolate the fundamental components from the harmonic components of the grid currents. This is achieved through the dq transformation (5). The quadrature component of the source current which is taken from dq transformation is directly passed through the LPF. Thus, the 50 Hz component of the source current is generated. Then this signal is applied to reproduce the reactive power compensation current by inversing the dq transformation (6). However, this reference current is in a quadrature axis. To achieve the reactive power compensation by the voltage controlled voltage source M-SHAPF, the reference current must be in the phase with the source voltage. Thus, the reference current is transformed by using only the ˈdˈcomponent of the inverse dq transformation. Engineering, Technology & Applied Science Research Vol. 6, No. 5, 2016, 1133-1138 1135 www.etasr.com Demirdelen et al.: A Modular Cascaded Multilevel Inverter Based Shunt Hybrid Active Power Filter… D. Selective Harmonic Reference Current Generation Selective harmonic elimination technique is generally based on the ideas of opposite harmonic injection (3rd, 5th, 7th, 9th,11th and 13th order) and it’s given to three phase voltage source inverter switches. In this paper, the passive filter part of the system is tuned on the 5th harmonic frequency. In addition, SHAPF compensates harmonics. However, 7th, 9th, 11th and 13th harmonics are still in the system with small amount. Thus, FFT methods is used for eliminating this harmonics. Figure 2(d) represents the FFT based selective harmonic elimination. Firstly, 7th, 9th, 11th and 13th order harmonics are extracted by FFT. Then, three phase selective harmonic reference current is generated by using “sine” operator. Fig. 1. Proposed System E. DC Link Voltage Controller * DCV is the dc link reference value for both harmonic and reactive power compensation selected 1.5 kV. By using the error signal generated by the conventional PI controller, the dq inverse transformation (7) produces the reference DC link control signals in the abc referential frame shown in Figure 2 (e). A limiter is also applied to avoid the overflow problem of the controller. DC link is controlled by the reactive component of the error signal. Thus, only the q component is used for dq inverse transformation. )7( 0 0 123 _ _ _                      errror dq cappic bcappi acappi VT V V V F. Multilevel Inverter Control , Final Reference Compensation Current and PWM Control Block In this proposed system a seven level modular cascaded multilevel inverter is used. Cascaded multilevel inverters include series H bridge inverters. Cascaded inverters have structurally no problem of dc-link voltage unbalancing. Thus, the cascaded inverter has been widely studied and used in fields of static VAR compensators (SVCs), power line conditioners, voltage stabilizers and hybrid active power filters. To compare with the diode clamped or capacitor clamped inverter, the cascaded inverter does not need any voltage clamping diodes or voltage balancing capacitors. Table I shows the switch combination of seven level cascaded multilevel inverter. TABLE I. SWITCH COMBINATION OF SEVEN LEVEL CASCADED MULTILEVEL INVERTER FOR EACH PHASE Switch State Voltage Vao S1 S2 S3 S4 S5 S6 S7 S8 S9 S10 S11 S12 3Vdc 1 0 0 1 1 0 0 1 1 0 0 1 2Vdc 1 0 0 1 1 0 0 1 0 0 1 1 Vdc 1 0 0 1 0 0 1 1 0 0 1 1 0 0 0 1 1 0 0 1 1 0 0 1 1 -Vdc 0 0 1 1 0 0 1 1 0 1 1 0 -2Vdc 0 0 1 1 0 1 1 0 0 1 1 0 -3Vdc 0 1 1 0 0 1 1 0 0 1 1 0 The final reference current consists of three phase harmonic reference current signals, three phase selective harmonic reference current signals, three phase reactive reference current signals and dc link control signals. The reference signal (In_harmonic_ref + In_fft_k_ref + In_reactive_ref + Vcappi_n) is generated using these signals together. Then, the reference signals are compared with carrier signals to generate switching signals shown in in Figure 2(f). III. SIMULATION RESULTS The simulation studies are carried out using PSCAD/EMTDC (three runs), aiming to evaluate the effectiveness and correctness of the control strategy used in the SHAPF under unbalanced/distorted grid voltage. The simulation parameters are given in Table II. The passive filters are tuned at 5th and the control signals of IGBTs are generated through the pulse width modulation generator whose amplitude and frequency of carrier wave are  1 and 10 kHz, Engineering, Technology & Applied Science Research Vol. 6, No. 5, 2016, 1133-1138 1136 www.etasr.com Demirdelen et al.: A Modular Cascaded Multilevel Inverter Based Shunt Hybrid Active Power Filter… respectively. Ed + + + ++ Ea Eb Ec Eq Ediff Ia_harmonic_ref Ic_harmonic_ref Ib_harmonic_ref Σ Σ - - + +Iq Id d q Id_lpf Iq_lpf Iq_fund Σ - +  ip kk Vcappi_a Limitter Vcappi_b Vcappi_c PWM Gate Signals Switching Signals S1n-12n Reference Vcappi_n In_harmonic_ref In_reactive_ref Σ + + + Harmonic Current Reference Generation Reactive Current Reference Generation DC Link Voltage Control Final Reference Compensation Current and PWM Control Block (b) (e) (f) Isa Isc Isb abc d q abc Ia_reactive_ref Ic_reactive_ref Ib_reactive_ref Iq d q (c) Isa Isc Isb abc d q abc0 d q abc 0 V*DC VDC VERROR Carrier1 Carrier2 Carrier3 (n=a,b,c) Differential Phase Lock Loop (Diff-PLL) Selective Harmonic Current Reference Generation FFT Ia_fft_k_ref SIN (d) Isa Isc Isb k x Isn_fft_k (k=7,9,11,13 n=a,b,c) _ _ Ib_fft_k_ref Ic_fft_k_ref (a) Σ + + In_fft_k_ref Fig. 2. Proposed Controller TABLE II. SIMULATION PARAMETERS Parameters Value Line Voltage 6.3 kV Line frequency 50 Hz Supply inductance (Ls) 1 mH Rectifier inductance (Ll) 0.6 mH Filter (CF,LF) 16 µF, 25 mH Load Resistances(Rload1 ) 100 Ω Load Inductances(Lload1) 600 mH Load Inductances(Lac1) 13 mH Switching frequency (fswitching) 10 kHz Simulation Step Time 20 µs Inductive Loads 1st Load ( Rload1 Lload1) 360 kVAR Nonlinear Load 60 kVAR Tuned freq. of series filter (ftuned) 250 Hz First case is that three phase grid voltages are balanced. It is ideal condition and in literature most articles consider this condition. As shown in Figure 3, the harmonic elements of the grid currents are almost eliminated. In the second case, one phase of grid voltages is distorted. 10% and 11th order harmonics is added to Phase A voltage. As shown in Figure 4, the reduced THD of the source current, while compensating harmonics, working distorted supply means, sinusoidal current is drawn from the source. Last case is that the grid voltages are unbalanced as the case in industrial applications. Phase C voltage has a lower value compared to other phase voltages. As shown in Figure 5, the harmonic elements of the grid currents are almost eliminated. Figure 6 represents that the source reactive power is nearly equal to zero for all cases. The passive filter supports a fixed reactive power which is equal to 220 kVAR. The load reactive power capacity is nearly 320 kVAR. Thus, the inverter part of SHAPF supplies the remaining reactive power compensation which is nearly equal to 100 kVAR. The SHAPF DC link voltage is stable for all cases shown as shown in Figure 6. Considering the simulation results, the proposed method can:  Provide reactive power and harmonic compensation  Reduce the THD of the source side current  Apply for medium voltage applications  work not only with distorted but also with unbalance grid voltages. IV. CONCLUSION A new control approach is investigated in order to ensure the ac current shaping, compensate the reactive power and regulate the dc voltage for a three phase modular cascaded multilevel inverter based shunt hybrid active power filter. The harmonic compensation is obtained by regulating the currents of the power systems. The reference reactive power compensation currents of the M-SHAPF are generated indirectly of the power systems. The dc link voltage control signals are based on the reactive power balance of system. The reactive power compensation is achieved successfully with a perceptible amount. The selective harmonic compensation Engineering, Technology & Applied Science Research Vol. 6, No. 5, 2016, 1133-1138 1137 www.etasr.com Demirdelen et al.: A Modular Cascaded Multilevel Inverter Based Shunt Hybrid Active Power Filter… performance is satisfactory. The simulation results of the three phase three wire SHAPF are illustrated to verify all discussion and analysis and also show the effectiveness of the proposed controller. Hence, the proposed M-SHAPF system can be considered an effective and economic solution for both harmonic and reactive power problems caused by the large capacity of linear and nonlinear loads under balanced, unbalanced and distorted grid voltages. 0.750 0.760 0.770 0.780 0.790 0.800 0.810 0.820 0.830 0.840 0.850 -8000 -6000 -4000 -2000 0 2000 4000 6000 8000 -100 -80 -60 -40 -20 0 20 40 60 80 100 -50 -40 -30 -20 -10 0 10 20 30 40 50 -100 -80 -60 -40 -20 0 20 40 60 80 a b c Three Phase Source Voltages(V) Three Phase Load Currents(A) Three Phase SHAPF Currents(A) Three Phase Source Currents(A) Fig. 3. Three Phase Source Voltages, Load Currents, SHAPF Current and Source Currents under balanced grid voltage 0.750 0.760 0.770 0.780 0.790 0.800 0.810 0.820 0.830 0.840 0.850 -8000 -6000 -4000 -2000 0 2000 4000 6000 8000 a b c -100 -80 -60 -40 -20 0 20 40 60 80 100 -50 -40 -30 -20 -10 0 10 20 30 40 50 -100 -80 -60 -40 -20 0 20 40 60 80 Three Phase Source Voltages(V) Three Phase Load Currents(A) Three Phase SHAPF Currents(A) Three Phase Source Currents(A) Fig. 4. Three Phase Source Voltages, Load Currents, SHAPF Current and Source Currents distorted grid voltage -8000 -6000 -4000 -2000 0 2000 4000 6000 8000 -100 -80 -60 -40 -20 0 20 40 60 80 100 -50 -40 -30 -20 -10 0 10 20 30 40 50 -100 -80 -60 -40 -20 0 20 40 60 80 0.750 0.760 0.770 0.780 0.790 0.800 0.810 0.820 0.830 0.840 0.850 a b c Three Phase Source Voltages(V) Three Phase Load Currents(A) Three Phase SHAPF Currents(A) Three Phase Source Currents(A) Fig. 5. Three Phase Source Voltages, Load Currents, SHAPF Current and Source Currents under unbalanced grid voltage 0.750 0.760 0.770 0.780 0.790 0.800 0.810 0.820 0.830 0.840 0.850 0 100 200 300 400 500 600 700 800 900 0 100 200 300 400 500 600 700 800 900 -350 -250 -150 -50 50 150 250 350 1.5185 1.5188 1.5190 1.5193 1.5195 1.5198 1.5200 1.5203 1.5205 1.5208 0.00 0.50 1.00 1.50 2.00 2.50 3.00 -2.00 -1.50 -1.00 -0.50 0.00 0.50 1.00 1.50 2.00 Source Reactive Power (kVAR) Load Reactive Power (kVAR) SHAPF Reactive Power (kVAR) SHAPF DC Link Voltage (kV) SHAPF DC Link Voltage (kV) Fig. 6. Source, Load, SHAPF reactive power and SHAPF DC link Voltage Engineering, Technology & Applied Science Research Vol. 6, No. 5, 2016, 1133-1138 1138 www.etasr.com Demirdelen et al.: A Modular Cascaded Multilevel Inverter Based Shunt Hybrid Active Power Filter… ACKNOWLEDGMENT The authors would like to acknowledge the Scientific and Technological Research Council of Turkey (TÜBİTAK Project Number: 115R327) and the Scientific Project Unit of Cukurova University (FDK-2016-5828) for full financial support. REFERENCES [1] X. Bails, L.M. Tolbert,“Efficiency improved and current balanced three- phase modular cascaded H bridge multilevel PV inverter for grid connected applications”, IEEE Energy Conversion Congress and Exposition (ECCE), pp. 4661–4669, 2014 [2] J. Turunen, M. Salo, H. Tuusa, “Comparison of three series hybrid active power filter topologies”, 11th International Conference on. Harmonics and Quality of Power, pp. 324–329, Sept. 2004 [3] D. Shaojun, L. Jianben, T. Kun, C. 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