Introduction

Question 1

List the different types of capacitors you know

Answer 1

• Aluminium electrolytic
• Ceramic capacitors
• Metallized film capacitors
• Tantalum capacitors
• Supercapacitors
• Power capacitors

Question 2

Classify the types of capacitors in terms of voltage and capacitance (cosmos chart)

Answer 2

• Aluminium electrolytic capacitors: medium to high capacitance (1uF-1F), low to medium voltage (5V-800V).
• Ceramic capacitors: low capacitance (1pF-1uF), medium voltage (15V-100V).
• Film capacitors: low to medium capacitance (2pF-100uF), low to high voltage (50V-1000V).
• Tantalum capacitors: low to high capacitance (1uF-1000uF), low voltage (1V-60V).
• Supercapacitors: very high capacitance (1F-1000F), low to medium voltage (1V-100V)
• Power capacitors: medium to high capacitance (100nF-1F), medium to high voltage (100V-above 1000V)

Question 3

General applications (cosmos chart) of different types of capacitors

Answer 3

• Ceramic C: coupling and RF, power supply, filtering.
• Film C: coupling and RF, power supply, snubber, power electronics.
• Tantalum C: power supply.
• Aluminium electrolytic C: power supply, power storage, power electronics.
• Power C: power electronics, power supply.
• Ultracapacitors: power storage.

Question 4

Fundamental definition of capacitor

Answer 4

• Parallel plates with area A separated by distance d.
• Equal charge q with different polarity is accumulated on the plates.
• Charges attract each other and distribute uniformly on the inner surfaces A of the plates with a charge density rho.
• Electric field is established between the plates proportional to charge density and dielectric constant of inner material.

Question 5

9 Fundamental equations of capacitors

Answer 5

• Divergence of E field = Electric charge density/Permittivity
• Electric field = charge density/permittivity
• Charge density = Electric charge/Area
• Electric field = 0 (outside the plates)
• Voltage = Electric field * distance = Electric charge * distance /(permittivity*Area)
• Electric charge on each plate = Capacitance*Voltage
• Capacitance (no dielectric) = permittivity*Area/distance
• Capacitance (dielectric) = permitivitty of material*Area/distance
• Energy stored = Capacitance*Voltage^2/2
• I = C*dv/dt
• Xc = 1/jwC
• W = (I^2)*ESR

Question 6

Explain the effect of introducing a dielectric between the plates of a capacitor

Answer 6

• Atoms inside the dielectric are polarized by the accumulated charges in each plate. Positive charge is induced on one surface and negative charge is induced on the other surface of the dielectric.
• This polarization creates an E field inside the dielectric opposite to the original E field without dielectric.
• The field inside the plates is therefore reduced.
• Reduction of E field implies a reduction of the voltage, but as the charge remains the same the capacitance must increase, as shown by the equation. In other words, it effectively reduces distance between the plates and therefore increases capacitance (in case of placing a conducto).

Question 7

Relative permittivity of paper, polypropelene, polyethylen, glass, AlO, BaTiO3

Answer 7

• Glass: 6-8
• Polypropylene: 2.1
• paper: 1-4
• Aluminium oxide: 9
• Barium titanate: 103-104
• Polyethylen: 2.4

Question 8

Main challenges of applications where capacitors are used

Answer 8

• Lifetime/reliability
• Ripple current
• Humidity
• Corrosion
• Recycling
• Cost
• Mechanical vibration
• Temperature
• Size and weight
• Breakdown voltage
• Parital discharge

Question 9

List different types of housing

Answer 9

• Can, box: Aluminium, steel, polymers.
• Polymer film, epoxy or PU resin.
• No housing
• Deck.

Question 10

List different 5 types of terminals for capacitors

Answer 10

• Wire
• Snap in
• Screw terminal
• SMD
• Solder lugs

Question 11

What is a general behaviour of capacitors when frequency increases

Very simple and basic answer

Answer 11

They start behaving as inductors

Question 12

Comparison between aluminium electrolytic and film C (2 ideas at least)

Answer 12

• Film capacitors are more reliable and can withstand higher voltages
• AL provide higher capacitance

Question 13

Why polypropylene has low dielectric constant

Answer 13

Because it lacks of polarization due the chemical/atomic structure (carbon atoms)

Question 14

Why do humidity reduces dielectric breakdown of air?

Answer 14

• Because water molecules can be easily polarized/ionized.
• Water is a dipole

Question 15

1 Advantage and 1 disadvantage of tantalum capacitors

Answer 15

• Expensive
• More reliable

Question 16

Principl by which E fields can be added

Answer 16

principle of superposition of fields

Question 17

Describe atomic dipoles effect

Answer 17

• An electric field in any material causes a displacement of electrons and protons relative to each other.
• In an insulator electron do not move a lot, but they shift a little bit. Although an atom or molecule remains neutral, there is a small separation of its positive and negative charges and it becomes a microscopic dipole.

Question 18

Formula of dipole moment of two charges

Answer 18

dipole moment = electric charge*separation

Question 19

Describe some properties of water in terms of electric dipoles and compare with other substances

Answer 19

• Water molecule is neutral but charges are not all at one point.
• It has a strong dipole moment due to assymetry of charges
• CO2 molecules for example have no dipole moment due to symmetry of the molecule

Question 20

what is the problem of sharp points on a conductor

Answer 20

• The E field is larger than in other regions because small amounts of charge on sharp regions can provide a large surface density and therefore high E field around this region.
• It is a problem since it will increase the probability of air/dielectric breakdown.

Question 21

5 List general properties of capacitors

Answer 21

• Operating principle based in E fields
• Opposes to change in voltage
• Stores energy when constant voltage is applied
• Keeps the energy stored and voltage after removal of external voltage (it makes capacitors dangerous/should be discharged)
• Acts as open circuit for DC current, current leads the voltage by 90° in AC circuits.
• As energy stores, mechanical force is produced between the conductors.

Question 22

Give a definition of permittivity

Answer 22

• Measure of resistance of a medium to form an E field.
• Permittivity is determined by the ability of a material to polarize in response to E field, and hence reduce the total E field inside the material.

Question 23

Is the capacitance constant against the voltage? if so write the new equation of C

Answer 23

• No, i.e. when the capacitor charges it affects its mechanical properties (force), causing the capacitance to change.
• In this case capacitance can be defined in terms of incremental changes of charge: C = dq/dv

Question 24

Formula of capacitance in series and parallel

Answer 24

• Series: 1/C=1/C1+1/C2…
• Parallel: C = C1+C2+…

Question 25

Explain general details of charging of capacitor

Answer 25

• At t=0, capacitor voltage is zero and current is maximum limited only by series R.
• The current exponentially decays with time and charge of capacitor exponentially increases.
• Eventually current through capacitor is zero.

Question 26

general definition of dielectric

Answer 26

• Insulator material that can be polarized by an applied E field.
• Electric charges do not flow inside the dielectric, but shift slightly from their equilibrium position (dielectric polarization).
• This creates an E field that reduces overall field in the dielectric.
• Weakly bonded molecules in the dielectric reorient to align with the E field.
• Atoms consists of a cloud of electrons surrounding a positive charge at the centre. The cloud is distorted by the E field and forms a dipole.
• When E field is removed atoms reorient to original state. The time required to do so is called relaxation time.
• Dielectric supports high E field while dissipating minimal energy as heat.

Question 27

Compare high and low dielectric constants materials based on capacitance, voltage and size

Answer 27

• High dielectric constant materials make possible to produce high-value capacitors in small sizes, but they cannot withstand high E fields (due to material properties and distance between electrodes)
• Low dielectric can withstand high E fields but provide low capacitance.

Question 28

Is dielectric breakdown reversible?

Answer 28

• Yes for components like gases or liquids when the voltage decreases below a critical point.
• Not for solid dielectrics.

Question 29

Is permittivity of dielectrics constant?

Answer 29

No, it tends to vary with T and sometimes with f and V (class II ceramics)

Question 30

5 factors that affect dielectric strength

Answer 30

1. Temperature
2. Frequency
3. Voltage
4. Shape of electrodes (sharp regions increase E field)
5. Impregnants (can fill air void in the dielectric and increase breakdown voltage)

Question 31

Some factors that affect capacitance are

Answer 31

1. Temperature.
2. Voltage (in ceramics for example, the E field applied changes the dielectric constant)

Question 32

What is the usual degradation of lifetime due to temperature rise

Answer 32

Each 10°C rise of temperature causes a 50% reduction of capacitor life (Arrhenius equation).

Question 33

Main characteristics of electrolytic capacitors

Answer 33

• High values of capacitance
• Unsuitable for filters, due to wide tolerance, polarized and frequency dependent capacitance.

Question 34

Are all electrolytic capacitors polarized

Answer 34

No, there are bipolar electrolytic where no polarizing voltage is needed.