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Aperçu

Welcome to the course material on Simple A.C. Circuits. In this topic, we delve into the fascinating world of Alternating Current (AC) circuits, which play a vital role in numerous electrical systems and devices we encounter in our daily lives. The key objectives of this course material revolve around understanding the concept of AC, distinguishing it from Direct Current (DC), analyzing the behavior of circuit elements like resistors, inductors, and capacitors in AC circuits, interpreting specific graphical representations, and examining the phase relationship between voltage and current in these elements.

To start our exploration, we will first focus on comprehending the fundamental disparities between AC and DC. Direct Current flows constantly in one direction, while Alternating Current cyclically changes its direction, oscillating back and forth. Understanding this dichotomy is essential as AC power is predominant in powering homes, industries, and various electronic devices due to its efficient transmission characteristics.

The behavior of resistors, inductors, and capacitors in AC circuits is a critical aspect that we will extensively cover. Resistors impede the flow of current, inductors store energy in the form of magnetic fields, and capacitors store energy in an electric field. These components exhibit distinct responses in AC circuits compared to DC circuits, necessitating a comprehensive understanding of their interactions with alternating voltages and currents.

Graphs play a pivotal role in visualizing the behavior of AC circuits. Specifically, we will delve into graphs of equations such as I – Io sin wt and E = Eo sin wt, which depict the current and voltage variations with respect to time. These graphical representations provide insights into the periodic nature of AC and aid in analyzing the magnitude and phase relationships between current and voltage.

Furthermore, our journey will involve exploring the phase relationships between voltage and current in circuit elements, namely resistors, inductors, and capacitors. Understanding the phase shifts in these elements is crucial for optimizing the efficiency of AC circuits and ensuring the proper functioning of electrical systems.

In applying the knowledge gained from this course material, you will develop the proficiency to solve complex problems involving AC circuits, thereby honing your analytical and problem-solving skills in the realm of electrical engineering. By the end of this comprehensive study, you will have a profound understanding of Simple A.C. Circuits and be equipped to tackle real-world challenges in the dynamic field of electrical technology.

Objectifs

Understand the concept of alternating current (AC)
Interpret graphs of equations I – Io sin wt and E = Eo sin wt
Examine the phase relationship between voltage and current in circuit elements
Distinguish between direct current (DC) and AC
Analyze the behavior of resistors, inductors, and capacitors in AC circuits
Apply knowledge to solve problems involving AC circuits

Note de cours

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Évaluation de la leçon

Félicitations, vous avez terminé la leçon sur Simple A.C. Circuits. Maintenant que vous avez exploré le concepts et idées clés, il est temps de mettre vos connaissances à lépreuve. Cette section propose une variété de pratiques des questions conçues pour renforcer votre compréhension et vous aider à évaluer votre compréhension de la matière.

Vous rencontrerez un mélange de types de questions, y compris des questions à choix multiple, des questions à réponse courte et des questions de rédaction. Chaque question est soigneusement conçue pour évaluer différents aspects de vos connaissances et de vos compétences en pensée critique.

Utilisez cette section d'évaluation comme une occasion de renforcer votre compréhension du sujet et d'identifier les domaines où vous pourriez avoir besoin d'étudier davantage. Ne soyez pas découragé par les défis que vous rencontrez ; considérez-les plutôt comme des opportunités de croissance et d'amélioration.

What is the term used to describe the phase relationship between voltage and current in circuit elements such as resistors, inductors, and capacitors in an AC circuit? A. Phase difference B. Amplitude ratio C. Frequency correlation D. Power factor Answer: Phase difference
In an AC circuit, how does the current behave in comparison to the voltage in a resistor? A. In-phase B. Out-of-phase by 90 degrees C. Out-of-phase by 180 degrees D. Out-of-phase by 270 degrees Answer: In-phase
Which type of circuit element in an AC circuit has the current lagging behind the voltage? A. Resistor B. Inductor C. Capacitor D. Diode Answer: Inductor
What is the graphical representation of E = Eo sin wt in an AC circuit? A. Sine wave B. Square wave C. Triangular wave D. Sawtooth wave Answer: Sine wave
How do inductors respond to changes in the applied AC voltage in a circuit? A. By storing energy in a magnetic field B. By converting electrical energy to heat C. By blocking the flow of current D. By changing their resistance value Answer: By storing energy in a magnetic field

Livres recommandés

	Fundamentals of Physics Sous-titre Electricity and Magnetism Éditeur John Wiley & Sons Année 2018 ISBN 978-1119462712
	Electric Circuits Sous-titre Alternating Current Circuits Éditeur Oxford University Press Année 2015 ISBN 978-0199339136

Questions précédentes

Vous vous demandez à quoi ressemblent les questions passées sur ce sujet ? Voici plusieurs questions sur Simple A.C. Circuits des années précédentes.

JAMB UTME - Physics - 2023 (Cliquez pour passer l'évaluation complète)

Question 1 Rapport

A generator manufacturing company accidentally made an AC generator instead of a DC generator. To fix this error,

the magnetic field needs to be made stronger

the split rings should be replaced with slip rings

the number of turns of the armature coil needs to be decreased

the slip rings should be replaced with split rings

Voir la réponse

WAEC SSCE - Physics - 2022 (Cliquez pour passer l'évaluation complète)

Question 1 Rapport

You are provided with a battery of e.m.f, E, a standard resistor, R, of resistance 2 $Ω$ , a key, K, an ammeter, A, a jockey, J, a potentiometer, UV, and some connecting wires.

(i) Measure and record the emf, E, of the battery.

(ii) Set up the circuit as shown in the diagram above with the key open.

(iii) Place the jockey at the point, U, of the potentiometer wire. Close the key and record the reading, i, of the ammeter.

(iv) Place the jockey at a point T on the potentiometer wire UV such that d = UT = 30.0 cm.

(v) Close the circuit, read and record the current, I, on the ammeter,

(vi) Evaluate I $^{1}$ .

(vi) Repeat the experiment for four other values of d = 40.0 cm, 50.0 cm, 60.0 cm and 70.0 cm. In each case, record I and evaluate I $^{1}$ .

(vii) Tabulate the results

(ix) Plot a graph with d on the vertical axis and I on the horizontal axis stalling both axes from the origin (0,0).

(x) Determine the slope, s, of the graph.

(xi) From the graph determine the value I $_{1}$ , of I when d = 0. (ci) Given that=s, calculate 8.

(xii) State two precautions taken to ensure accurate results.

(xii) Given that $\frac{E}{δ}$ = s, calculate $δ$ .

(b)(i) Write down the equation that connects the resistance, R, of a wire and the factors on which it depends. State the meaning of each of the symbols.

(ii) An electric fan draws a current of0.75 A in a 240 V circuit. Calculate the cost of using, the fan for 10 hours if the utility rate is $ 0.50 per kWh.

Réponse

(a) OBSERVATIONS

(i) Value of E correctly read and recorded to at least 1 d.p in volts.

(ii) Value of i correctly read and recorded to at least 1 d.pin amperes.

(iii) Five values of d correctly determined and recorded to at least 1 d.p in cm.

(iv) Five values of I correctly read and recorded to at least 1 d.p in amperes and in trend.
Trend; As d increases, I decreases

(v) Five values of I $^{1}$ correctly evaluated to at least 3 s.f.

(vi) Composite table showing at least d, I, and I $^{- 1}$ .

(ii) P = IV

Power P = $\frac{240 \times 0.75}{100}$

0.18kw

Energy consumed in 10hr = 0.18 x 10

= 1.8kWh

Cost of energy = 1.8 x 0.5 = $0.9

Cost of energy = $\frac{P x cost x time}{100}$

$\frac{0.7 \times 240 \times 10}{1000}$

= $0.9

Détails de la réponse

(a) OBSERVATIONS

(i) Value of E correctly read and recorded to at least 1 d.p in volts.

(ii) Value of i correctly read and recorded to at least 1 d.pin amperes.

(iii) Five values of d correctly determined and recorded to at least 1 d.p in cm.

(iv) Five values of I correctly read and recorded to at least 1 d.p in amperes and in trend.
Trend; As d increases, I decreases

(v) Five values of I $^{1}$ correctly evaluated to at least 3 s.f.

(vi) Composite table showing at least d, I, and I $^{- 1}$ .

(ii) P = IV

Power P = $\frac{240 \times 0.75}{100}$

0.18kw

Energy consumed in 10hr = 0.18 x 10

= 1.8kWh

Cost of energy = 1.8 x 0.5 = $0.9

Cost of energy = $\frac{P x cost x time}{100}$

$\frac{0.7 \times 240 \times 10}{1000}$

= $0.9

Voir la réponse

NECO SSCE - Physics - 2009 (Cliquez pour passer l'évaluation complète)

Question 1 Rapport

A transformer has an efficiency of 92.5%. the ratio number of turns in the primary coil to that in the secondary coil is 128 : 45. If the current passing through the secondary coil is 9.0A, calculate the current passing through the primary-coil.

2.93A

3.16A

3.42A

25.60A

27.68A

Voir la réponse