Closed Loop Reactive Power Control by A SPWM STATCOM Based On Modular Multilevel Cascade Converter for Electric Welding Machine

DOI : 10.17577/IJERTV2IS110834

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Closed Loop Reactive Power Control by A SPWM STATCOM Based On Modular Multilevel Cascade Converter for Electric Welding Machine

  1. Dineshkumar Department of Electrical and Electronics Engineering (P.G)

    Sri Ramakrishna Engineering College, Coimbatore, India

    Prof. D. Prakash

    Asst. Professor( SR.G) Department of Electrical and Electronics Engineering Sri Ramakrishna Engineering College,Coimbatore, India

    Dr. R. Mahalakshmi Professor and Head, Department of Electrical and Electronics engineering Sri Krishna College of Technology , Coimbatore, India

    Abstract

    This paper presents the application based on single delta bridge cells (SDBCs) to a STATic synchronous COMpensator (STATCOM) for closed loop reactive power control both positive sequence and negative sequence. The SDBC is characterised by cascade connection of H-bridge (or full bridge) converter cells per leg. The SDBC based sinusoidal pulse width modulation (SPWM) technique based STATCOM to control reactive power in closed loop with reduced harmonics and switching losses for the application of welding machine. In this proposed method to circulate the circulating current among the delta connected cluster and to stable the dc mean voltage in the each capacitor in the cluster arm for control the reactive power. In this method minimum number of power electronics switches are used and simultaneously to minimize the total harmonic distortion (THD). The performance of the proposed method is developed using MATLAB/Simulink software.

    Keywords – Single delta bridge cells (SDBC), Sinusoidal pulse width modulation(SPWM), STATic synchronous COMpensator (STATCOM), Total Harmonic Distortion(THD)

    1. INTRODUCTION

      In recent years FACTS devices are used for reactive power compensation in electrical power system network. One of the many devices is a STATCOM which can be used to regulate the flow of reactive power in the system independent of other system

      parameters. The Modular Multilevel Cascade Converters (MMCCs) is expected as next generation power converters suitable for high voltage or medium voltage applications without line frequency transformers. The MMCC has various converter cell configurations: a) Single Star Bridge Cell (SSBC), b) Single Delta Bridge Cell (SDBC), c) Double Star Chopper Cell (DSCC) and d) Double Star Bridge Cell (DSBC) among above four configurations the SDBC, DSCC, and DSBC have the capability to control reactive power but the SDBC is better choice than others because it has the count ratio of 1.7 [1]. Flicker compensation of welding machine requires the control of reactive power. The SDBC has the capability of controlling reactive power mainly on negative sequence because it allows a current to circulate among their each cluster arms.

      The SDBC based STATCOM with stair case modulation and pulse width modulation are used for operation of each H bridge connected in each arm of the clusters. In stair case modulation no feedback loop is formed to control the circulating current among delta connected clusters.

      The aim of this paper is to provide simulation results of a SDBC based sinusoidal pulse width modulation (SPWM) STATCOM for closed loop reactive power control (both positive and negative sequence) [5] for welding machine. In this control method that is characterised by forming feedback loop of the circulating current among the delta connected clusters. In this method five level cascade multilevel converter is used, to implement the hall effect voltage sensor on each H bridge side to sense the voltage level of the each capacitor and feedback to the processor to control the amplitude of the carrier signal and also for balancing the capacitor voltage in each arm. As a result

      the STATCOM output voltage can be controlled by the modulation index. It improves the resultant STATCOM output voltage appears only as sidebands centered around the frequency of 2Nfs [2], this is provided that the voltage across the dc capacitor of each inverter is the same. It is followed by simulation results for downscaled model rated at 440V and 2kVA SDBC based STATCOM.

      Figure 1. Block Diagram

      The block diagram of closed loop reactive power control scheme is shown in Figure 1. The system detects each dc capacitor voltage VC both active (p*) and reactive (q*) powers and a dc supply voltage Vc as input signals to the A/D unit. The A/D unit consisting

      of seven A/D converters takes in the analog signals and then it converts them into digital signals. A digital signal processor (DSP) unit using a 16-bit DSP takes in the digital signals and produces the voltage commands after completing the digital processing to the gate driver circuit for produce pulses to GTOs. The welding machine is connected to the point of common coupling. The point of common coupling is introduced between source and cascaded H bridge inverter. The phase locked loop (PLL) block is used to synchronize internal control signals with the line phase for d q transformation and inverse dq transformations [6].

    2. CIRCUIT CONFIGURATION OF THE SDBC

      The Figure 2 shows the detailed circuit configuration of the 440V, 2kVA STATCOM used in this simulation. Each cluster of the SDBC consists of cascade connection of three bridge cells. Three clusters are connected in delta configuration via a single

      coupled inductor L. The SDBC is connected to a three phase ac mains of 440V (line to line rms).

      Figure 2. SDBC Circuit configuration

      Here Vab, Vbc and Vca are the cluster voltages and iab, ibc and ica are the cluster currents and p and q are the instantaneous active and reactive powers at the PCC. The following relations exist between the compensating currents and the cluster currents :

      ia=iabica ; ib=ibciab ; ic =icaibc (1) Let the circulating current flowing inside the delta connected clusters be iZ. It is defined as

      iZ = (iab + ibc + ica) (2)

      Each carrier frequency of sinusoidal PWM for bridge cells was set as fc = 2.5 kHz. The dc capacitor was set as Vc= 100µF. AC source inductance and coupled inductor were set as Ls = 0.5µH and L =10nH. Welding machine load was designed to set as input voltage of 20V and output load current of 100A.

    3. DESIGN OF THE 2kVA STATCOM

      The Figure 2 shows the circuit configuration of the 2 kVA delta configured STATCOM cascading two H-bridge PWM converters in each phase. All the GTOs have the same voltage rating and current rating as 4.5 kV and 1.7 kA. Each H bridge has floating dc capacitors with maximal dc mean voltage capability of 1000V. The sinusoidal PWM with a carrier frequency of 2.5 kHz is applied to a cluster of six cascaded H-bridge converters in each phase. The ac voltage of each cluster becomes a 5 level line to neutral PWM waveform with the lowest harmonic sideband center 10kHz.

    4. CHOICE OF WELDING MACHINE

      In this paper an arc welding machine is chosen for a load because the arc process needs a large amount of

      current, up to 650A but at a relatively low arc voltage

      10 to 40V with a typical high voltage main power supply and 230 to 400V. This type of equipment produces very high disturbances in the low voltage network and also in high voltage network, where they are mostly connected. The arc welding machines input currents have low frequency oscillations which can give rise to flicker. The group of devices in the range of above 5MVA connected to the high voltage grid for industrial manufacturing purposes like Shielded Metal Arc Welding (SMAW), Tungsten Arc Welding, Gas (GTAW) also known as TIG, Metal Arc Welding (GMAW) popularly known as Meal Inert Gas (MIG). These devices draw reactive power from supply so it causes low power factor, it heats the welding transformer, etc.., these drawbacks are overcome by using single delta bridge cell. In this paper 20V, 100A welding machine model is designed to represent as an arc welding model [8].

    5. CONTROL METHOD OF THE SDBC

The main theme of this paper is to control reactive power and to reduce the level of the multilevel inverter and to maintain dc capacitor voltage control in each cluster to be same. Voltage control of the six floating dc capacitors can be divided into the following:

  1. Cluster balancing control.

  2. Circulating current control.

  3. Individual balancing control.

    1. CLUSTER BALANCING CONTROL

      The figure 3.1 shows the block diagram of the cluster balancing control. The voltage major loop forces the average voltage of each cluster namely Ca, Cb, and Cc to follow the average voltage of the three clusters C , where they are defined as:

      =

      =

      =

      Figure 3.1. Cluster balancing control

      Here and are instantaneous values containing both ac and dc components. It is desirable to extract only the dc components (i.e ). The low pass filter is used to extract the dc component.

    2. CIRCULATING CURRENT CONTROL

      The Figure 3.2 shows the block diagram of the circulating current control. The current minor loop forces iZ to follow its command i*Z, producing the voltage command V*A that is common to the three clusters.

      Figure 3.2. Circulating current control

    3. INDIVIDUAL BALANCING CONTROL

The Figure 3.3 shows the block diagram of the individual balancing control. It forms an active power between the ac voltage of each bridge cell and the corresponding cluster current [3] and [4]. The voltage

commands are given by

(3)

The following equation is obtained from (1) and (2)

(4)

+ + = 0 (5)

Figure 3.3 Individual balancing control

The sum of the voltage commands is equal to zero.

  1. MATLAB SIMULINK MODEL

    1. REACTIVE POWER CONTROL USING SDBC BASED STATCOM

      SDBC based STATCOM for closed loop reactive power control for welding machine block diagram is

      Discrete,

      This means that no interference occurs between the individual balancing control and the circulating current

      s = 5e-005 s powergui

      Conn1 A

      Vabc

      A A

      Iabc

      Iabc Vabc Icuv w

      V

      Is

      Subsystem3

      Out1 Out2 Out3

      A

      1. A

        control.

        Conn2 B

        Conn3 C

      2. B a

        b

      3. C

      c

      1. B B

        A B C

        A B C

      2. C C

      A B C

      A B C

      6. REACTIVE POWER AND OVER ALL VOLTAGE CONTROL

      In1 In2PWM

      In3

      A

      PWM B

      C

      A Iabc a

      B

      b

      C c

      v

      v

      +

      VC

      v

      v

      +

      VC1

      +

      +

      – v

      VC2

      Scope1

      Scope3

      V

      Is

      Vdc2

      The Figure 4 shows the block diagram of the active and reactive power and overall voltage control [7] in which p* and q* represent the power commands of p and q at the PCC. The dc component of q* is adjusted to control positive sequence reactive power. A couple of second order components (100 Hz) with the same amplitude but a phase difference of 90° are superimposed on p* and q* respectively to control reactive power particularly on negative sequence. The line to line voltage commands V*ab, V*bc, and V*ca are determined by decoupled current control of the compensating currents.

      The voltage balancing control is not to regulate the instantaneous voltages of the dc capacitors at their voltage reference but to regulate the mean voltages over a time of 8ms using a moving average method with a frequency of 100 Hz.

      Figure 5.1 SDBC based STATCOM

      shown in figure 5.1. In this method the SDBC bridge is used to control reactive power with feedback loop control. The output voltage of the bridge can be control by changing the modulation by closed loop. Circulating current is injected in the delta connected cluster for the control of reactive power due to load disturbances. The reactive power can be control by adjust the circulating current among delta connected clusters.

    2. REACTIVE POWER CONTROL AND OVER ALL VOLTAGE

      The figure 5.2 shows the reactive power control and overall voltage control block. The above mention control strategies are implemented in this block for control reactive power in closed loop manner. The modulation index can be varied by parameters obtained from the various control method implemented in the system.

      1

      Iabc

      Vabc 2

      Sum of Elements1

      RMS

      (discrete)

      Discrete RMS value

      1/3

      Iz

      Gain1

      Sum of Elements

      Scope4

      1/3

      Vc

      Gain

      Scope2

      1

      z

      Unit Delay2

      1

      z

      Unit Delay1

      Iabc abc2dq Idq0

      Angle

      abc2dq Vdq0

      Vabc Angle

      Sin_Cos

      Scope5

      Scope6

      Vcdc id

      iq

      Add4

      id* iq*

      q d

      PI

      VA*

      id iq q

      Vsq

      Vdq0

      dq0

      Scope7

      abc Vuv w*

      Vabc

      PQ

      Iabc

      Scope1

      Vsd d

      Decoupled

      sin_cos

      dq0_to_abc Transformation

      3

      Icuvw

      3-phase Instantaneous

      Active & Reactive Power

      6

      Fo=100Hz

      1/2

      VCu(dc)

      In1 In2

      Out1

      1

      Out1

      Multimeter

      VCv (dc)

      1

      z

      Unit Delay

      Fo=100Hz

      Fo=100Hz

      1/2

      1/2

      In1 In2 In3 In4 In5 In6 In7 In8 In9 In10 In11 In12

      Scope3

      Add3

      Subsystem4

      1/3

      VBu

      Vbv

      Vbw

      VCw(dc)

      VC(dc)

      Vc(dc))

      iz*

      1/3

      In3

      In5 Out2 In6

      In7

      Out3

      In8

      Subsystem5

      2

      Out2

      3

      Out3

      Scope8

      Figure 4. Reactive power control and overall voltage control

      Figure 5.2. Reactive power control and over all voltage control

    3. SINGLE DELTA BRIDGE CELL CONFIGURATION

      The Figure 5.3 shows the delta connected H Bridge in SDBC. Each cell has floating dc capacitor ,

      the initial value of each capacitors has maintain by the system manner. The switches (GTOs) in the SDBC has 4.5kV capability so it can withstand higher level of input voltage. The clusters are connected in delta configuration manner.

      20

      15

      10

      Current(A)

      Current(A)

      5

      0

      -5

      -10

      -15

      -20

      0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1

      Time(s)

      Figure 5.5. Circulating current in delta cluster

      Figure 5.3. Single delta bridge cell configuration

    4. WELDING MACHINE MODEL

      The figure 5.4 shows welding machine model. Welding machine model is representing as a welding

      Figure 5.6. Capacitor voltage in each cluster

      x 104

      transformer. The values of the primary and secondary resistances and inductances are chosen form arc welding transformer. The rating of the machine is designed to provide 20V, 100A rating. The welding transformer output is given to bridge rectifier circuit to produce arc.

      8

      p*(kW)

      p*(kW)

      6

      4

      2

      0

      0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1

      Time (s)

      x 104/p>

      0

      -1

      q*(kvar)

      q*(kvar)

      -2

      -3

      -4

      -5

      -6

      0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1

      Time (s)

      Figure 5.7. Active and reactive power

      Figure 5.4. Welding machine

    5. SIMULATION RESULTS

      The following figure shows the output waveforms of SDBC based STATCOM for closed loop reactive power control in welding machine.

      40

      C Phase Current(A) B Phase Current(A) A Phase Current(A

      C Phase Current(A) B Phase Current(A) A Phase Current(A

      20

      0

      -20

      -40

      40

      20

      0

      -20

      -40

      40

      20

      0

      -20

      -40

      50

      Voltage(V)

      Voltage(V)

      40

      30

      0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9

      Time(s)

      0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9

      Time(s)

      0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9

      Time(s)

      Figure 5.8. Input current to welding transformer

      20

      10

      Input voltage(V)

      Input voltage(V)

      500

      0

      -500

      Input current(A)

      Input current(A)

      500

      0

      -500

      0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1

      Time(s)

      0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1

      Time(s)

      0

      150

      Current(A)

      Current(A)

      100

      50

      0

      0 0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4

      Time(s)

      0 0.05 0.1 0.15 0.2 0.25 0.3 0.35 0.4

      Time(s)

      Figure 5.9. Output voltage and current

      Figure 5.4. Input voltage and current

      The single delta bridge cell is connected to the point of common coupling it inject circulating current in SDBC bridge to the supply for controlling reactive power the results are shown in figure 5.4. The capacitor voltage control is shown in figure 5.6 Capacitor voltage remains same up to 8ms after its decreased to lower level and maintain constant level. Figure 5.7 shows the active and reactive power control. Figure 5.8 shows the

      input current obtained in welding machine. Figure 5.9 shows the output voltage and current waveforms obtained from the welding transformer.

      7.6 CONCULSION

      In this paper the simulation of an arc welding machine reactive power is controlled by using single delta bridge cell and it acts as a STATCOM to control reactive power by injecting circulating current among delta connected arms in SDBC. The closed loop which helps to control the circulating current by change the modulation index of the carrier signal used in sinusoidal pulse width modulation for control the output voltage of STATCOM. The low voltage steps at the terminal of each cluster to make closely correlated to reducing the THD values. THD value of ia in phase A is 0.54%. Active power and reactive power both are controlled on concurrent execution. In this single delta bridge cell topology can be applicable to control reactive power in adjustable speed drives, induction furnaces, grid connected transformer, transmission line, etc,

  2. REFERENCES

  1. H. Akagi, Classification, terminology, and application of the modular multilevel cascade converter (MMCC), IEEE Trans. Power Electron., vol. 26, no. 11, pp. 31193130, Nov. 2011.

  2. Y. Liang and C. O. Nwankpa, A new type of STATCOM based on cascading voltage-source inverters with phase-shifted unipolar SPWM, IEEE Trans. Ind. Appl., vol. 35, no. 5, pp. 1118 1123, Sep./Oct. 1999.

  3. M. Hagiwara and H. Akagi, Control and experiment of pulse width modulated modular multilevel converters, IEEE Trans. Power Electron., vol. 24, no. 7, pp. 17371746, Jul. 2009.

  4. J. A. Barrena, L. Marroyo, M. A. Rodriguez, and J. R. Torrealday, Individual voltage balancing strategy for PWM cascaded H-Bridge converter based STATCOM, IEEE Trans. Ind. Electron., vol. 55, no. 1, pp. 2129, Jan. 2008.

  5. C. Han, Z. Yang, B. Chen, A. Q. Huang, B. Zhang, M. R. Ingram, and A. Edris, Evaluation of cascade-multilevel-converter-based STATCOM for arc furnace flicker mitigation, IEEE Trans. Ind. Appl., vol. 43, no. 2, pp. 748755, Mar./Apr. 2007.

  6. H. Akagi, S. Inoue, and T. Yoshii, Control and performance of a transformerless cascade PWM STATCOM with star configuration, IEEE Trans. Ind. Appl., vol. 43, no. 4, pp. 10411049, Jul./Aug. 2007.

  7. Makoto Hagiwara,Ryo Maeda and Hirofumi Akagi Negative-Sequence Reactive-Power Control by a PWM STATCOM Based on a Modular Multilevel Cascade Converter (MMCC- SDBC) Negative-Sequence Reactive-Power Control by a PWM STATCOM Based on a Modular Multilevel Cascade Converter (MMCC- SDBC), IEEE Trans. Power Electron., vol. 48, no. 2, pp. 720729, Mar/Apr. 2012.

  8. Sawicki. A, Switon. and Sosinski. R,

Process Simulation in the AC Welding ArcCircuit Using a Cassie-Mayr Hybrid Model, American Welding Society and the Welding Research Council, Mar 2011.

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