Electrical Theory I (ENG3322)

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Title: Electrical Theory I (ENG3322)

1
Charging of a capacitor

One of the functions of a capacitor is its
ability to store up charge when a potential
difference is applied across the positive and
negative plates.
Energy is stored in the electric field. When a
voltage is applied across a capacitor, current
rushes into the plates of the capacitor,
developing a potential difference across the
capacitor, therefore the potential difference
between the battery and the capacitor become
smaller and the flow rate of electrons become
smaller.
The charging process continues until the
capacitor becomes fully charged. The charging
current follows an exponential curve.

2
Charging of a capacitor/2
3
Charging of a capacitor/3
4
Charging of a capacitor/4

Insert initial (boundary) conditions, if the
capacitor is initially uncharged, then at t 0,
q 0
C2 EC, substitute into equation 1

5
Charging Curve
6
Charging Curve

From the charging equation, we noticed that the
rate of charging is determined by the exponential
curve that is in term determined by the RC
constant.
The term RC is termed the time constant since it
affects the rate of charge. Mathematically, this
is the time taken for the capacitor to reach
0.632 of the fully charged value.

7
Duration of Transient

Theoretically, capacitors will never be fully
charged according to the charging equation.
Thus, for all practical purposes, transients can
be considered to last for only five times of the
time constant. I.e. the capacitor is said fully
charged after
5 RC.
After 5 time constant, q, Vc and I will be over
99 to their final values.

8
Charging of Capacitor-Example one
9
Charging of Capacitor-Example one

An uncharged capacitor of 2000 micro-Farad is
connected to a 100 volt D.C. supply in series
with a current limiting resistor of 5000 Ohms,
calculate
i) The voltage of the capacitor at the end of
8 seconds charging
ii) The charging current at the end of 8
seconds
iii) The time taken for the capacitor to be
charged to 80 volts.

10
Charging of Capacitor-Solution to Example one

11
Charging of Capacitor-Solution to Example one/2

12
Charging of a initially charged capacitor

13
Charging of a initially charged capacitor
14
Example to charging of a capacitor with residual
charge and initial voltage

A 3,000µF capacitor has an initial voltage of 50
Volts is further charged by a 200 volts D.C.
supply in series with a 2 k-Ohm resistor.
Calculate the voltage across the terminals of the
capacitor after 10 seconds.
Solution Using the formula for capacitor with
an initial voltage,

15
Alternative solution to previous problem

Alternatively, if you do not wish to memorize the
formula for charging a capacitor with an initial
charge, you can first find the time required to
charge an uncharged capacitor to the initial
voltage, then add the extra time for charging to
find the final voltage.
Solution
Time required to charge an uncharged 3,000µF
capacitor to 50 volts can be found by applying
the formula

16
Alternative solution to previous problem/2

Total time equivalent the capacitor is to be
charged from zero volt 1.7261 10 11.7261
Seconds

17
Alternative solution to previous problem/3

18
Discharge of a capacitor

19
Discharge of a capacitor/2

20
Discharge of a capacitor/3

Substitute boundary condition, at t 0,
Voltage across C E, q EC
C2 EC
(Note that the negative sign indicate that the
current is opposite to the charging currents
direction)

21
Discharge curve
22
Discharge of capacitor example

A 1000µF capacitor previously charged to 80
Volts is to be discharged through a resistance of
20 k-Ohms. Find the voltage across the terminals
of the capacitor at the end of 15 seconds.