Determine the direction of current flow along the circuit in the figure during the time intervalte (0,60) [s] when the instantaneous position of the moving bar across the conducting rails is givenby x, (t) = 10+cost under the constant magnetic flux density field B = 3.x, [T] .120X2CCWCWR*, (t)Seçtiğiniz cevabın işaretlendiğini görene kadar bekleyiniz. Soruyu boş bırakmak isterseniz işaretlediğiniz seçeneğe tekrar tıklayınız.Counterclockwise (CCW) directionAClockwise (CW) directionBNo current is induced on the wire.

The position of rail is given as: x1(t)=10+cosπ120t, t∈(0,60) s When t=0s x1(t)=10+cos0=11 When…

Determine the direction of current flow along the circuit in the figure during the time interval te (0,60) [s] when the instantaneous position of the moving bar across the conducting rails is given by x, (t) = 10+cos 120 under the constant magnetic flux density field B = 3â, [T]. X2 CCW CW R fox x; (1) eçtiğiniz cevabın işaretlendiğini görene kadar bekleyiniz. Soruyu boş bırakmak isterseniz işaretlediğiniz seçeneğe tekrar tıklayınız. Counterclockwise (CCW) direction A Clockwise (CW) direction B No current is induced on the wire.

Determine the direction of current flow along the circuit in the figure during the time interval te (0,60) [s] when the instantaneous position of the moving bar across the conducting rails is given by x, (t) = 10+cos 120 under the constant magnetic flux density field B = 3â, [T]. X2 CCW CW R fox x; (1) eçtiğiniz cevabın işaretlendiğini görene kadar bekleyiniz. Soruyu boş bırakmak isterseniz işaretlediğiniz seçeneğe tekrar tıklayınız. Counterclockwise (CCW) direction A Clockwise (CW) direction B No current is induced on the wire.

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

See similar textbooks

Similar questions

An iron core has 250 times more flux density than air for the same field intensity. What is the value of its relative permeability?
QUESTION 3 4 In a ferromagnetic material, the relation between flux and flux density is O linear O nonlinear O not related O inverse
Given the master slave circuit below and the clock and input timing diagram, draw the output waveform. Assume QA is zero before time A. CLK KA Ka А в с DE F G H CLK UL UL JA UT KA
Calculate the flux crossing surface of area 1 m2 with 37° to the x axis and located at x=1 m if flux density given as D=100e-0.1xax µc/m?. O 452 x10-6 C O 303 x10-6 C O 361x10-6 C O 272 x10-6 C O 184 x10-6 C
In the magnetic circuit shown below, what is the flux density produced if the relative permeability of the core material under the given condition is 1000? 5 A-> 100 turns R = 5 cm
Figure 1 shows a square coil of side 4.5 cm. A battery is connected to the coil and produces a current of 6.8 A. The coil is placed in a uniform magnetic field of flux density 5.67 mT as shown in Figure 1. A D 0o B Figure 1 Calculate the size and direction of the electromagnetic force that will act on side AB. Calculate the size and direction of the electromagnetic force that will act on side BC. Describe the motion of the frame immediately after the current in the frame is switched on. The battery is removed from the coil and the coil is nechanically rotated 90° clockwise. State the direction of the induced current on side AB. North Pole South Pole
13 - Which of the following is true about the magnetic field in the Biot-Savart law?I. is inversely proportional to r.II. It is inversely proportional to r2.III. It is directly proportional to the current. A) Yalnız I B) II ve III C) Yalnız III D) I ve III E) Yalnız II
EX3 Voltage Sag 400 V network short circuit power is 1000 kVA (reactive). A 10 kW induction motor is connected. The motor takes 6-times nominal current when started (assume inductive current). Calculate the voltage drop as a) per unit value, b) per cent value, c) volts in line voltage, d) volts in phase voltage.
The chart applies to a particular magnetic field system. The flux linkage is in weber-turns and the current is in amperes. X1 and X2 each denote some specific value of a distance parameter X in the system. The system state point has moved from point a to point b. Assume that the motion is very, very slow. 1. Determine the input energy 2. Determine the change in field energy 3. Determine the energy output of the system 4. What is the inductance of the system at point b
For the magnetic system given below, assume infinite permeability for the core. 1=0.5 A 6 cm- N = 1000 turns Core cross-section: 2 cm x 2 cm -6 cm 4 mWb 8 mWb 0 mWb 10 mWb $₂ 0.5 cm 8 cm The flux in the air gap (ignoring fringing) would approximately be
Can someone explain this problem step by step? please
Consider the magnetic circuit in Figure. Assuming that the core µ= 1000µo has a uniform cross section of 4 cm2,N= 400 , the flux density in the air gap. 0.2 A L = 42 cm 4 = 0.1 cm 35.4 mwb 60.5 mwb 70.8 mwb Non of These