;please label the problems 1-4 Full-Wave Rectifier with LC FilterFor the circuit in Figure 14, determine VMax (peak after diode drops), Vr (ripple voltage), y (ripple factor),and the DC output voltage VDC. Vin_pp=22.8Vpp@60Hz (Vpeak-11.4V before the diode drops), RL=1350,Ci=100uF, Li=10mH, Rx=2792, VD=0.7V. Recommendation is to solve for VMax, then VDC. Keep in mind thatVMax_AC is the peak ripple voltage and V, is the peak-to-peak ripple voltage (they are off by a factor of 2).From WallOutlet120Vrms(340Vpp)TransformerSketch the output signal.DO NOT Connectthese two wires!D₂D3L1ProbeC1RLProbe GNDGNDFigure 14: Full-Wave Rectifier with LC Choke Filter Repeat the calculations for C-200uF and C-2200uF.Repeat the calculations for RL=27092, C=100uF.

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Answered: Full-Wave Rectifier with LC Filter For…

Electric Motor Control

10th Edition

ISBN:9781133702818

Author:Herman

Publisher:Herman

Chapter59: Motor Startup And Troubleshooting Basics

Section: Chapter Questions

Problem 12SQ: How is a solid-state diode tested? Explain.

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Similar questions

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How is a solid-state diode tested? Explain.
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In the clamping circuit below, assume the diode has Von-0.7V and V₁ is a sinusoidal wave with a peak-to-peak amplitude of 10V. How much is the maximum value of the output voltage signal (Vmax)? And how much will it be if we set V₂=2V? Input V1 C1 0.1e-6 9.3 V and 7.3 V 9.3 V and 11.3 V 11.3 V and 7.3 V O 7.3 V and 12.0 V O 12.0 V and 7.3 V Output D1 1N4148 .tran 30-3 V2 0 Vmax V(output) 0.0ms putput MAN Input 0.6ms 1.2ms V(input) 1.8ms 2.4ms 3.0ms
find the output voltage
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A full wave bridge rectifier is supplied from 230V, 50Hz and uses a transformer of turns ration 15:1. It uses load resistance of 50 ohms. Calculate load voltage and ripple voltage. Assume ideal diode and transformer. Assume ripple factor equals to 0.482. a.Load Voltage= 13.8 V; Ripple Voltage=6.652 V b.Load Voltage= 15.6 V; Ripple Voltage=7.611 V c.Load Voltage= 21.3 V; Ripple Voltage=8.410 V d.Load Voltage= 25.1 V; Ripple Voltage=10.442 V

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