ModulaÃ§Ã£o Vetorial Aplicada ao Retificador TrifÃ¡sico PWM - Ivo Barbi

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237X_S53 cmd2a 0 $N_0013 $N_0014 qualyuniy20k_S53X_S54 cmd3a 0 $N_0015 $N_0016 qualyuniy20k_S54D_D49 fase1 $N_0011 DbreakD_D50 comum $N_0011 DbreakD_D51 $N_0017 comum DbreakD_D52 $N_0017 fase1 DbreakD_D53 comum $N_0013 DbreakD_D54 fase2 $N_0013 DbreakD_D55 $N_0018 fase2 DbreakD_D56 $N_0018 comum DbreakD_D57 fase3 $N_0015 DbreakD_D58 comum $N_0015 DbreakD_D59 $N_0019 comum DbreakD_D60 $N_0019 fase3 DbreakD_D62 $N_0014 $N_0018 DbreakD_D63 $N_0016 $N_0019 DbreakD_D64 0 $N_0019 DbreakD_D65 0 $N_0018 DbreakD_D66 0 $N_0017 DbreakD_D67 $N_0015 Vo DbreakD_D68 $N_0013 Vo DbreakD_D69 $N_0011 Vo DbreakE_E41 cmd1a 0 TABLE { V(DA, Vtri) }+ ( (0,0) (.08,15) )E_E42 cmd2a 0 TABLE { V(DB, Vtri) }+ ( (0,0) (.08,15) )V_V73 setorAp $N_0020+PULSE 0 15 0 1n 1n 1.3888888ms 16.666666mV_V80 $N_0020 0+PULSE 0 15 15.277777m 1n 1n 1.3888888ms 16.666666mV_V74 setorBn 0+PULSE 0 15 1.38888m 1n 1n 2.777m 16.666666mV_V75 setorCp 0+PULSE 0 15 4.166666m 1n 1n 2.777m 16.666666mX_S40 setorAp 0 Eq1 DB qualyuniy20k_S40X_S41 setorBn 0 um DB qualyuniy20k_S41X_S42 setorCp 0 Eq3 DB qualyuniy20k_S42X_S43 setorAn 0 Eq5 DB qualyuniy20k_S43X_S44 setorBp 0 um DB qualyuniy20k_S44X_S45 setorCn 0 Eq6 DB qualyuniy20k_S45X_S46 setorAp 0 Eq2 DC qualyuniy20k_S46X_S47 setorBn 0 Eq3 DC qualyuniy20k_S47X_S48 setorCp 0 um DC qualyuniy20k_S48X_S49 setorAn 0 Eq4 DC qualyuniy20k_S49X_S50 setorBp 0 Eq6 DC qualyuniy20k_S50X_S51 setorCn 0 um DC qualyuniy20k_S51V_V76 setorAn 0+PULSE 0 15 6.9444444m 1n 1n 2.777m 16.666666mV_V78 setorCn 0+PULSE 0 15 12.5m 1n 1n 2.777m 16.666666mV_V77 setorBp 0+PULSE 0 15 9.7222222m 1n 1n 2.777777m 16.666666mX_H9 $N_0021 $N_0022 I2 0 qualyuniy20k_H9X_H8 $N_0023 $N_0024 I3 0 qualyuniy20k_H8V_V52 $N_0021 $N_0025+SIN 0 180 60 0 0 210V_V53 $N_0023 $N_0025+SIN 0 180 60 0 0 -30D_D61 $N_0012 $N_0017 DbreakV_V51 $N_0026 $N_0025+SIN 0 180 60 0 0 90X_H7 $N_0026 $N_0027 I1 0 qualyuniy20k_H7R_R67 $N_0028 fase3 .11R_R66 $N_0029 fase2 .11R_R65 $N_0030 fase1 .11L_L10 $N_0027 $N_0030 790uH IC=78.13L_L11 $N_0022 $N_0029 790uH IC=-39.065L_L12 $N_0024 $N_0028 790uH IC=-39.065R_R85 Vo 0 8E_SUM58 $N_0031 0 VALUE {V($N_0032)+V(um)}E_GAIN90 Eq3 0 VALUE {1 * V($N_0031)}E_DIFF62 $N_0033 0 VALUE {V(um,$N_0034)}E_GAIN91 Eq6 0 VALUE {1 * V($N_0033)}E_SUM59 $N_0035 0 VALUE{V($N_0036)+V($N_0037)}E_GAIN92 Eq1 0 VALUE {1 * V($N_0035)}E_DIFF63 $N_0037 0 VALUE {V(um,$N_0038)}E_GAIN93 $N_0038 0 VALUE {1.225 * V(Dalfa)}E_GAIN94 $N_0036 0 VALUE {0.707 * V(Dbeta)}E_GAIN95 Eq2 0 VALUE {1 * V($N_0039)}E_DIFF64 $N_0039 0 VALUE {V($N_0041,$N_0040)}E_DIFF65 $N_0041 0 VALUE {V(um,$N_0042)}E_GAIN96 $N_0042 0 VALUE {1.225 * V(Dalfa)}E_GAIN97 $N_0040 0 VALUE {0.707 * V(Dbeta)}E_GAIN98 $N_0032 0 VALUE {1.414 * V(Dbeta)}E_SUM60 $N_0043 0 VALUE{V($N_0044)+V($N_0045)}E_GAIN99 Eq4 0 VALUE {1 * V($N_0043)}E_SUM61 $N_0045 0 VALUE {V($N_0046)+V(um)}E_GAIN100 $N_0046 0 VALUE {1.225 * V(Dalfa)}E_GAIN101 $N_0044 0 VALUE {0.707 * V(Dbeta)}E_GAIN102 Eq5 0 VALUE {1 * V($N_0047)}E_DIFF66 $N_0047 0 VALUE {V($N_0049,$N_0048)}E_SUM62 $N_0049 0 VALUE {V($N_0050)+V(um)}E_GAIN103 $N_0050 0 VALUE {1.225 * V(Dalfa)}E_GAIN104 $N_0048 0 VALUE {.707 * V(Dbeta)}E_GAIN105 $N_0034 0 VALUE {1.414 * V(Dbeta)}E_MULT58 $N_0051 0 VALUE {V(coseno)*V(Dq)}E_MULT59 $N_0052 0 VALUE {V(seno)*V(Dd)}E_MULT60 $N_0053 0 VALUE {V(seno)*V(Dq)}E_MULT61 $N_0054 0 VALUE {V(coseno)*V(Dd)}E_DIFF67 Dbeta 0 VALUE {V($N_0051,$N_0052)}E_SUM63 Dalfa 0 VALUE {V($N_0053)+V($N_0054)}V_CONST13 um 0 DC 5E_DIFF68 $N_0055 0 VALUE {V($N_0057,$N_0056)}X_U30A 0 $N_0058 V15p V15n Idref TL082R_R92 $N_0055 $N_0058 10kR_R93 $N_0060 $N_0059 100kX_U31A 0 $N_0061 V15p V15n $N_0059 TL082R_R94 $N_0063 $N_0062 100kE_DIFF69 erroq 0 VALUE {V(0,Iq)}X_U32A 0 $N_0064 V15p V15n $N_0062 TL082E_DIFF70 errod 0 VALUE {V(Idref,Id)}E_SUM64 Dq 0 VALUE {V($N_0065)+V($N_0062)}E_DIFF71 Dd 0 VALUE {V($N_0059,$N_0066)}R_R96 errod $N_0061 5.166kR_R97 erroq $N_0064 5.166kE_GAIN106 $N_0065 0 VALUE {0.186 * V(Id)}E_GAIN107 $N_0057 0 VALUE {5/400 * V(Vo)}C_C45 $N_0061 $N_0059 2.65n IC=-2.62C_C46 $N_0061 $N_0060 1.32n IC=-2.62C_C47 $N_0064 $N_0062 2.65n IC=-0.338C_C48 $N_0064 $N_0063 1.32n IC=-0.338E_GAIN108 $N_0066 0 VALUE {0.186 * V(Iq)}C_C39 Vo 0 816u IC=400C_C49 $N_0067 Idref 646n IC=-1.94R_R95 $N_0058 $N_0067 7.7kV_V83 $N_0056 0+PULSE 5 5.5 30m 10u 10u 75m 126mE_E43 cmd3a 0 TABLE { V(DC, Vtri) }+ ( (0,0) (.08,15) )V_V79 Vtri 0+PULSE 0 4.95 0 49.99u 49.99u 10n 100u.subckt qualyuniy20k_S34 1 2 3 4S_S34 3 4 1 2 Sbreak-X1RS_S34 1 2 1G.ends qualyuniy20k_S34.subckt qualyuniy20k_S35 1 2 3 4S_S35 3 4 1 2 Sbreak-X1RS_S35 1 2 1G.ends qualyuniy20k_S35.subckt qualyuniy20k_S36 1 2 3 4S_S36 3 4 1 2 Sbreak-X1RS_S36 1 2 1G
238.ends qualyuniy20k_S36.subckt qualyuniy20k_S37 1 2 3 4S_S37 3 4 1 2 Sbreak-X1RS_S37 1 2 1G.ends qualyuniy20k_S37.subckt qualyuniy20k_S38 1 2 3 4S_S38 3 4 1 2 Sbreak-X1RS_S38 1 2 1G.ends qualyuniy20k_S38.subckt qualyuniy20k_S39 1 2 3 4S_S39 3 4 1 2 Sbreak-X1RS_S39 1 2 1G.ends qualyuniy20k_S39.subckt qualyuniy20k_S52 1 2 3 4S_S52 3 4 1 2 Sbreak-X1RS_S52 1 2 1G.ends qualyuniy20k_S52.subckt qualyuniy20k_S53 1 2 3 4S_S53 3 4 1 2 Sbreak-X1RS_S53 1 2 1G.ends qualyuniy20k_S53.subckt qualyuniy20k_S54 1 2 3 4S_S54 3 4 1 2 Sbreak-X1RS_S54 1 2 1G.ends qualyuniy20k_S54.subckt qualyuniy20k_S40 1 2 3 4S_S40 3 4 1 2 Sbreak-X1RS_S40 1 2 1G.ends qualyuniy20k_S40.subckt qualyuniy20k_S41 1 2 3 4S_S41 3 4 1 2 Sbreak-X1RS_S41 1 2 1G.ends qualyuniy20k_S41.subckt qualyuniy20k_S42 1 2 3 4S_S42 3 4 1 2 Sbreak-X1RS_S42 1 2 1G.ends qualyuniy20k_S42.subckt qualyuniy20k_S43 1 2 3 4S_S43 3 4 1 2 Sbreak-X1RS_S43 1 2 1G.ends qualyuniy20k_S43.subckt qualyuniy20k_S44 1 2 3 4S_S44 3 4 1 2 Sbreak-X1RS_S44 1 2 1G.ends qualyuniy20k_S44.subckt qualyuniy20k_S45 1 2 3 4S_S45 3 4 1 2 Sbreak-X1RS_S45 1 2 1G.ends qualyuniy20k_S45.subckt qualyuniy20k_S46 1 2 3 4S_S46 3 4 1 2 Sbreak-X1RS_S46 1 2 1G.ends qualyuniy20k_S46.subckt qualyuniy20k_S47 1 2 3 4S_S47 3 4 1 2 Sbreak-X1RS_S47 1 2 1G.ends qualyuniy20k_S47.subckt qualyuniy20k_S48 1 2 3 4S_S48 3 4 1 2 Sbreak-X1RS_S48 1 2 1G.ends qualyuniy20k_S48.subckt qualyuniy20k_S49 1 2 3 4S_S49 3 4 1 2 Sbreak-X1RS_S49 1 2 1G.ends qualyuniy20k_S49.subckt qualyuniy20k_S50 1 2 3 4S_S50 3 4 1 2 Sbreak-X1RS_S50 1 2 1G.ends qualyuniy20k_S50.subckt qualyuniy20k_S51 1 2 3 4S_S51 3 4 1 2 Sbreak-X1RS_S51 1 2 1G.ends qualyuniy20k_S51.subckt qualyuniy20k_H9 1 2 3 4H_H9 3 4 VH_H9 .02VH_H9 1 2 0V.ends qualyuniy20k_H9.subckt qualyuniy20k_H8 1 2 3 4H_H8 3 4 VH_H8 .02VH_H8 1 2 0V.ends qualyuniy20k_H8.subckt qualyuniy20k_H7 1 2 3 4H_H7 3 4 VH_H7 .02VH_H7 1 2 0V.endsqualyuniy20k_H7
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FLÁBIO ALBERTO BARDEMAKER BATISTAM
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MODULAÇÃO VETORIAL APLICADA A RET
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Abstract of Thesis presented to UFS
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3.3.1 - Vetores Disponíveis.......
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6.2.2 - Dimensionamento dos Indutor
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B.2 - Netlist para a Simulação do
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LISTA DE SIMBOLOS1. Símbolos Adota
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5. Sub-Índices UtilizadosSímboloS
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2Nesta área, podem ser citados est
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4As referências que tratam deste c
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6PD A1D B1D C1iO ( t)S A1D A3S B1D
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8o Análise da forma de implementa
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10Capítulo 2 - Modulação Vetoria
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12Aplicando a transformação αβ0
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14T 1 representa o intervalo de apl
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16TT′ = ⋅T11 ST1+T2TT′ = ⋅T
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18Tabela 2.6 - Seqüência de vetor
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20A Fig. 2-5 mostra a razão cícli
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22A definição dos setores é infl
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24O sistema original com referencia
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26RSEé a resistência equivalente
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28diA(t) diC(t)2⋅ vA( t) + vC( t)
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30Aplicando esta transformação à
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32Através da Fig. 2-11 é possíve
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34ComoTXD⋅ XD= 1⎡ cos( ω ⋅t)
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536PS A1S B1S C1iO( t )D A1D B1D C1
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38De forma semelhante, foi aplicado
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40200100vAiA( t)( t)0-100-2000s 5ms
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42800mVDbeta( t)Dalfa( t)400mV0V-40
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44As razões cíclicas das fases A,
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46Capítulo 3 - Modulação Vetoria
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48As etapas de operação para o Se
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50Na implementação dos vetores di
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52Tabela 3.2 - Sinais de comando pa
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Page 71 and 72:
56T 02T 12T 2T 12T 02cmd Atcmd Btcm
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58As razões cíclicas dos eixos α
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60Verifica-se também que a distrib
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623.4.1. Cálculos Preliminares e C
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64• Corrente média nos diodos D
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66Tabela 3.11 - Relações entre os
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68s + ωCI( s)=−KI⋅s ⋅ s +ZI(
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70A resposta ao degrau de referênc
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72⎛s + ω V ⎞⎜ ⋅ ⋅lim⎜s
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74A resposta ao degrau de referênc
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76No detalhe da Fig. 3-25 observa-s
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78450V450440V440430420VVo420410400V
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801.0V0.5VDd( t)Dq( t)0V0s 10ms 20m
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8220V20V10VSEL>>0VV(cmd1a)20V10VSEL
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84Os valores apresentados na Tabela
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86Neste caso, são definidos os mes
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884.3. Modulação Vetorial4.3.1. V
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94T 22T 12T 0T 12T 22cmd Atcmd Btcm
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96Neste caso, também se observa qu
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984.4. Dimensionamento do Estágio
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5102As relações para outros sub-s
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104100.0V87.5V75.0V62.5V50.0V30ms 4
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106450V450440V440430420VVo420410400
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1081.0V0.5VDd( t)Dq( t)0V0s 10ms 20
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1101.0uV1.0uV0VSEL>>-1.0uVV(cmd1a)2
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112200V200V0V0V-200V-277V20ms 24ms
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114A Fig. 4-33 mostra a forma de te
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1164.7. ConclusãoO retificador tri
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118Neste caso, são consideradas me
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120120V110V100V90V9.6ms 10.0ms 10.4
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122A Fig. 5-10 apresenta as razões
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124100V75V50V30ms 40ms 60ms 80ms 10
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126450V450440V440430420VVo420410400
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1285.4.1. Vetores Utilizados e Sina
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1305.4.2. Seqüência de Vetores e
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1325.4.3. Modelagem do RetificadorP
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134O projeto dos controladores para
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136Verifica-se a mesma dinâmica ap
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138200vA( t)100iA( t)0-100-2000s 10
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AADa10.90.80.70.60.50.40.30.20.1ALB
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142Como principal diferença entre
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144PPPD A1D B1D C1iO() tD A1D B1D C
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146Neste caso, a razão cíclica n
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148Para uma análise mais aprofunda
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150Tabela 6.1 - Especificações de
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152C2P ⋅ ⋅T= = 4296 μFO hold-u
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156• Perdas totais diodo D 34 :PD
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158RθT− THD34 AHAmax= =PSEMI0,13
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160Para f A= 10 kHz e considerando
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162+15VR493.3k25K13 1C29 2.2pR51R50
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164Saída 2: -15V/500mA para a alim
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1667.2.1. Malha de CorrenteA funç
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168νZIνCI= 2⋅π⋅ fv = 6498 ra
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170• Expressão (7.25): erro de c
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172A freqüência de corte para a m
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174Na Fig. 7-7 é mostrada a respos
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176A posição dos pólos em malha
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178A Fig. 7-14 mostra a lógica uti
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180referênciaNa Fig. 7-19 é mostr
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182O comportamento das razões cíc
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184604020IA,IB,IC (A)0-20-40-600.4
Page 201 and 202: 1867.5. Programação7.5.1. Fluxogr
Page 203 and 204: 188É reservada uma região da mem
Page 205 and 206: 190senoides utilizadas nas transfor
Page 207 and 208: 192vO() ttFig. 7-31 - Comportamento
Page 209 and 210: 1947.5.8. Definição dos Setores e
Page 211 and 212: 196vA () tiA() ta) Tensão de refer
Page 213 and 214: 198A Fig. 8-4 mostra os sinais de c
Page 215 and 216: 200Fig. 8-6 - Razões cíclicas par
Page 217 and 218: 202a) Correntes de entrada para 177
Page 219 and 220: 204Na Fig. 8-10 (a) observa-se a te
Page 221 and 222: 206DA( t )DB( t)DC( t)iA( t )Fig. 8
Page 223 and 224: 208Tabela 8-3 - Comparação entre
Page 225 and 226: 210Neste caso, observa-se uma maior
Page 227 and 228: 212Na Fig. 8-22 (a) observa-se tens
Page 229 and 230: 214Neste caso, observa-se que as fo
Page 231 and 232: 216Estas grandezas apresentam forma
Page 233 and 234: 218VS( t)iS( t )V ( t)D1iD1( t )a)
Page 235 and 236: 2208.5.2. Operação com V L = 380
Page 237 and 238: 222Tabela 8-7 - Fator de potência.
Page 239 and 240: 224Na Fig. 8-41, na Fig. 8-42 e na
Page 241 and 242: 226CONCLUSÃO GERALForam demonstrad
Page 243 and 244: 228dos valores teóricos, validando
Page 245 and 246: 230R83C386.94kV15n714nVo5/400R82 TL
Page 247 and 248: 232V_V46 V15n 0 DC -15D_D43 $N_0005
Page 249 and 250: I234ANEXO B. Diagrama Esquemático
Page 251: 236um5um1Eq1um1Eq4Dalfa1.225Dalfa1.
Page 255 and 256: 240R97C497.7kV15n646nVo5/400R92 TL0
Page 257 and 258: 242E_SUM26 $N_0009 0 VALUE{V($N_001
Page 259 and 260: 244ANEXO D. Dimensionamento do Est
Page 261 and 262: 246D.2. Dimensionamento dos Indutor
Page 263 and 264: 248⎧ vA(t) + vB(t) + vC(t) = 0⎪
Page 265 and 266: 250P 0,613⋅V −2⋅η⋅VI = ⋅
Page 267 and 268: 252ππ⎧⎫6 61 ⎪⎪IS = ⋅⎨
Page 269 and 270: 254ID3456MEDdiodos D I3456 .0⎧⎫
Page 271 and 272: 256ANEXO E. Esquemas Elétricos das
Page 273 and 274: 258C7100pF1110U2ALF347324111+-V+V-O
Page 275 and 276: 260GNDVsincA10k56nR54C31+15VR473.3k
Page 277 and 278: 262Barra de PinosBarra de Pinos1Bar
Page 279 and 280: 264int10: B int10int11: B int11int1
Page 281 and 282: 266LDP #DP_EVBSPLK #0000h, T3CONSPL
Page 283 and 284: 268SACL IDrefSATMAR *,AR4LDP #IDref
Page 285 and 286: 270; Dqlinha (total)LDP #DqlinhaPAD
Page 287 and 288: 272LDP #KD_1LT KD_1MPY DalfaSPACLDP
Page 289 and 290: 274CLRC SXMCLRC OVM; testa Inibe pa
Page 291 and 292: 276REFERÊNCIAS BIBLIOGRÁFICAS[1]
Page 293 and 294: 278[21] AREDES, M.; Active Power Li
Page 295 and 296: 280[44] BOTTERÓN, F.; Análise, Pr
Page 297: 282[67] BORGONOVO, Deivis; Análise
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ModulaÃ§Ã£o Vetorial Aplicada ao Retificador TrifÃ¡sico PWM - Ivo Barbi

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