Introduction
We know that a capacitor consists of two plates of conductors separated by an isolated distance and is also known as a dielectric. The capacitor limits or regulates the current when connected to an alternating current source, but it does not completely prevent charge drift. The capacitor gradually charges and discharges as the current reverses throughout each half-cycle. The highest charging current occurs while the capacitor’s plates are not charged, hence the charging process is not linear or instantaneous. Similar to the capacitor, once it is completely charged, its charge starts to drop dramatically. The capacity of a capacitor to hold a charge on its plates is known as capacitance. When a capacitor is connected to a voltage source in a DC circuit, current flows for the brief period of time required to charge the capacitor. The voltage across the conductive plates increases as charge accumulates on them, reducing the current. The circuit current zeroes out after the capacitor is fully charged.
Capacitance in AC circuits and capacitive reactance
A capacitor’s estimated capacity to store energy in an AC circuit is known as capacitance. The ratio of an electric charge to the corresponding difference in its electric potential is known as capacitance.
$$C=\frac{d Q}{d V}$$
Where dQ and dV are the charge and potential difference across capacitors, respectively. The capacitance may also be defined as the property of a capacitor to store the charge. The correlation between charging current (I) and the capacitors at which the capacitors supply voltage changes is given by
$$I=C \frac{d Q}{d V}$$
Capacitive reactance
Capacitive reactance is the resistance to the flow of electricity through the AC capacitor. It is calculated in ohm and denoted by \(X_C\) and measured in the units of Ω. It is calculated mathematically using the provided formula.
$$X_C=\frac{1}{2 \pi f C}=\frac{1}{\omega C}$$
Where f is the frequency, C is the capacitance and ⍵=2πf.
The ratio of the effective current to the voltage across the capacitor is another way to describe the capacitive reactance. We get the conclusion that capacitive reactance is inversely linked to frequency from the aforementioned connection. This implies that a drop in frequency across the capacitor will result in a decrease in capacitive reactance, and vice versa.
Improving your Science concepts. Study Science Preparation for classes 6th, 7th, and 8th.
How does a capacitor work in AC?
The capacitor is directly linked to the AC supply in an AC circuit. The capacitor goes through a process of charging or discharging and blocks DC when an AC source is applied. The capacitor also partially obstructs the AC signal. Reactance is the term used to describe a capacitor’s properties in reaction to an AC signal. The capacitor has a short circuit in AC.
AC Capacitor Circuits?
An AC capacitor circuit directly connects the AC supply to the capacitor to allow current to flow through the circuit. The capacitor’s plates are constantly being charged and discharged as a result of the AC supply.
Role of capacitor in AC circuit
As long as there is a source, the capacitor will constantly charge and discharge. The time constant, however, governs whether it fully charges (transforms electrical energy into charge to store between two plates) or fully discharges (charges into electrical energy). We must use a load to charge a capacitor. The time constant is RC, where C is the capacitance and R is the load resistance of the circuit. The capacitor starts to charge when a power source is placed in its path. When fully charged, it will wait for the appropriate time to release the energy it has accumulated.
Role of capacitor in DC circuit
The capacitor starts to charge as soon as a DC supply is connected since DC sources have continuous voltage. Once fully charged, it will wait for the right time to release the charge it has saved. The outcome is that it is an open circuit after being fully charged. As a result, the capacitor acts as a component of an open circuit. The charge is continually charged and discharged with an alternating current, though, due to the variable voltage. The capacitor, therefore, performs the role of a resistor. In this instance, reactance is used in place of resistance, and a capacitor’s reactance is equal to
$$
\frac{1}{2 \pi f C} .
$$
The function of a capacitor in an AC circuit
Electrical circuits contain capacitors, which store electrical energy and raise the circuit’s power factor.
$$
\text { Power factor }=\frac{\text { Real Power }}{\text { Apparent Power }}
$$
AC through the capacitor (Derivation)
Suppose Q is the charge on the capacitor at a given time t, and the instantaneous voltage is V across the capacitor, then we can write,
$$
V=\frac{Q}{C}
$$
The voltage across the source and the capacitor is uniform. Then, according to Kirchhoff’s loop rule
$$
V=V_m \sin \omega t
$$
From the above two equations, we can write that,
$$
V_m \sin \omega t=\frac{Q}{C}
$$
Again,
$$
I=\frac{d Q}{d t}
$$
$$
I=\frac{d}{d t}\left(C V_m \sin (\omega t)\right)=\omega C V_m \cos (\omega t)
$$
Now, as we know,
$$
\begin{gathered}
\cos (\omega t)=\sin \left(\omega t+\frac{\pi}{2}\right) \\
I=I_m \sin \left(\omega t+\frac{\pi}{2}\right) \\
I_m=\frac{V_m}{\left(\frac{1}{\omega C}\right)}
\end{gathered}
$$
\(\frac{1}{2 \pi f C} \) is the capacitive reactance and is denoted by \(X_C\).
So,
$$
I_m=\frac{V_m}{X_C}
$$
Summary
The capacitor is an electrical part that creates a direct connection with the voltage of the source of alternating current. The capacitor alters its charge or discharge in response to a change in the supply voltage. With no real current travelling through the capacitor, the circuit’s current will first flow in one direction before switching to the other. In a circuit with direct current, things are different. The capacitor plate contains both positive and negative charges when current passes through it when it is linked to a direct current circuit. In many diverse sectors, including energy storage, filters, rectifiers, and other things, capacitors are used. Additionally, it is utilised in circuits to increase voltage and smooth out current swings.
Frequently Asked Questions
1. What is capacitive reactance?
Ans: The capacitive reactance in an electric circuit is the resistance that a capacitor presents to the flow of alternating current
2. State Kirchhoff’s voltage law.
Ans: The algebraic sum of potential differences and electromotive forces is zero in a closed loop.
3. State the role of the capacitor in the AC circuit.
Ans: The charge is continually charged and discharged in an AC circuit due to variable voltage. The capacitor, therefore, performs the role of a resistor. In this case, reactance is used in place of resistance, and a capacitor’s reactance is equal to \(\frac{1}{2 \pi f C} \).
4. State the role of the capacitor in the DC circuit.
Ans: The capacitor starts to charge as soon as a DC supply is connected because a DC source’s voltage is constant. Once fully charged, it will wait for the right time to release the charge it has saved. The outcome is that it is an open circuit after being fully charged. As a result, the capacitor acts as a component of an open circuit.
5. What is an electrolytic capacitor?
Ans: An electrolytic capacitor is a capacitor in which ion mobility makes conduction feasible. A liquid or gel with a high ion concentration is called an electrolyte.