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Why Ceramic Capacitor Are More Popular than Others?

  • Contents

Ⅰ Introduction

 

A capacitor is an electrical device that stores energy as an electric field. It consists of two metal plates separated by a dielectric or non-conducting material. Fixed capacitance and variable capacitance are the two broad categories of capacitors. The most common are fixed capacitance capacitors, but variable capacitance capacitors are also available. Rotary or trimmer capacitors are examples of these. Fixed capacitance capacitors are classified as film capacitors, ceramic capacitors, electrolytic capacitors, and superconductor capacitors. Follow the link to learn more about the various types of capacitors. This article goes into greater detail about the ceramic capacitor.

 

 

Images of  Capacitors

 

 

Catalog

Ⅰ Introduction

Ⅱ Ceramic Capacitor Basics

2.1 What is a Ceramic Capacitor?

2.2 Ceramic Capacitor Polarity and Symbol

2.3 Types and Properties of Ceramic Capacitors

2.4 Ceramic Capacitor  Classes

Ⅲ Why Ceramic Capacitors Mostly Used in Electronic Circuit than Others?

3.1 Applications and Uses of Ceramic Capacitor

3.2  Properties or Advantages of Ceramic Capacitors

Ⅳ How to Read Ceramic Capacitor?

4.1 Where to Use a Ceramic Capacitor?

4.2 How We Read Ceramic Capacitor Value?

4.3 Calculate Ceramic Capacitor Value

4.4 Some Examples

Ⅴ FAQ

 

 

Ⅱ Ceramic Capacitor Basics

 

2.1 What is a Ceramic Capacitor?

 

The capacitor value is unchangeable.  The working ceramic material acts as the dielectric, and it is a ceramic capacitor constructed of two or more alternating layers of ceramic and it has a metal layer acting as the electrodes, and the composition of the ceramic material defines the electrical behavior and thus applications.

 

As per below video of ceramic capacitors:

 

 

What is CERAMIC Capacitor _ Uses _ complete information in English

 

 

2.2 Ceramic Capacitor Polarity and Symbol

 

Ceramic capacitors are the most common type of capacitor found in all electrical devices, and they use a ceramic material as the dielectric. Ceramic capacitors are non-polarity devices, which means they have no polarities. As a result, we can connect it to a circuit board in any direction.

 

As a result, they are far safer than electrolytic capacitors. The symbol for a non-polarised capacitor is shown below. Many capacitors, such as tantalum beads, do not have polarity.

 

 

Ceramic Capacitor Polarity and Symbol

 

 

 

2.3 Types and Properties of Ceramic Capacitors

 

Ceramic capacitors come in three varieties, though other styles are available:

 

  • Resin-coated leaded disc ceramic capacitors for through-hole mounting.
  • Multi-Layer Ceramic Capacitors with Surface Mount (MLCC).
  • Microwave bare lead-free disc ceramic capacitors that are designed to fit into a PCB slot.

 

different types of ceramic capacitors

 

 

Ceramic disc capacitors

 

Ceramic disc capacitors are made by coating a ceramic disc on both sides with silver contacts. These devices can be made from multiple layers to achieve higher capacitances. Ceramic disc capacitors are typically through-hole components that are dwindling in popularity due to their size. If capacitance values allow, MLCCs are used instead. Ceramic disc capacitors have capacitance values ranging from 10pF to 100F and voltage ratings ranging from 16 volts to 15 kV and higher.

 

Multi-layer ceramic capacitor (MLCC)

 

MLCCs are fabricated by precisely combining finely ground granules of paraelectric and ferroelectric materials and then layering the mixture with metal contacts. Following the completion of the layering, the device is heated to a high temperature and the mixture is sintered, resulting in a ceramic material with the desired properties. The resulting capacitor is essentially made up of many smaller capacitors connected in parallel to increase the capacitance. MLCCs have 500 layers or more, with a minimum layer thickness of about 0.5 microns. As technology advances, layer thickness decreases, and higher capacitances for the same volume are achieved.

 

 

2.4 Ceramic Capacitor  Classes

 

Different ceramic capacitor classes are defined based on the working temperature range, temperature drift, and tolerance:

 

Class 1 Ceramic Capacitors

 

  • These are the most temperature-stable capacitors. They have nearly linear properties.
  • The most commonly used dielectric compounds are.
  • Magnesium Titanate is used to achieve a positive temperature coefficient.
  • Calcium Titanate is used in capacitors that have a negative temperature coefficient.

 

Class 2 Ceramic Capacitors

 

  • Class 2 capacitors perform better at the price of volumetric efficiency, but at the expense of lower accuracy and stability. As a result, they are typically used for decoupling, coupling, and bypass applications where precision is not critical.
  • Temperature range: -50 to +85 degrees Celsius
  • The dissipation factor is 2.5 percent.
  • Accuracy ranges from average to poor.

 

Class 3 Ceramic Capacitors

 

  • Class 3 ceramic capacitors have a high volumetric efficiency but a low dissipation factor. It is unable to withstand high voltages. Barium Titanate is a common dielectric.
  • Temperature range of +10C to +55C will cause a -22% to +50% change in capacitance for a Class 3 capacitor.
  • Dissipation factor: 3 to 5%.
  • It will have a low level of accuracy (typically 20% or -20/+80%).

 

Class 3 is typically used for decoupling or in other power supply applications where accuracy is not critical.

 

 

Ⅲ Why Ceramic Capacitors Mostly Used in Electronic Circuit than Others?

 

Many circuits, particularly electronic circuits, use ceramic capacitors, as you may have noticed. Ceramic capacitors are largely used over electrolytic or other capacitors.

 

Ceramic capacitors

 

 

3.1 Applications and Uses of Ceramic Capacitor

 

  • In electronic sensor circuits, ceramic capacitors are used.
  • Ceramic capacitors are used in the transmission and reception of electronic signals.
  • Ceramic capacitors are applied in circuits such as audio mixers, controllers, and equalizers.
  • Ceramic capacitors are suitable for frequency-dependent circuits, such as electronic filter circuits, audio circuits, radio signal transmitters, and receiver circuits.
  •  Resonant circuits, like radio frequency communication system, needs ceramic capacitors, too.
  • Ceramic capacitors are used in alternating current circuits for no polarity such as high voltage protection circuits, power circuit breakers, and so on.
  • Ceramic capacitors are used in direct current motors to reduce radio frequency noise.
  • Ceramic capacitors can also be used as Bypass Capacitors.
  • Why Ceramic Capacitors mostly used in Electronic Circuit?

 

 

3.2  Properties or Advantages of Ceramic Capacitors

 

  1. Ceramic capacitors are available in extremely small sizes, which is a significant benefit. Because of the numerous electronic circuits, in fact, most modern electronic circuits necessitate the use of small size capacitors.

 

  1. Many critical electronic circuits necessitate the use of very small capacitors. Ceramic capacitors are available in a wide range of sizes.

 

  1. Ceramic capacitors can provide very high stability; in fact, they offer a wide range of stability.

 

  1. Ceramic capacitors have a low temperature coefficient and a higher voltage breakdown characteristic.

 

     5. Ceramic capacitors are the best choice for high-frequency applications.

 

 

Ⅳ How to Read Ceramic Capacitor?

 

Two reference tables

 

Marking Capacitance (pF) Capacitance (ìF)
101 100 pF 0.0001 ìF
221 220 pF 0.00022 ìF
471 470 pF 0.00047 ìF
102 1,000 pF 0.001 ìF
222 2,200 pF 0.0022 ìF
472 4,700 pF 0.0047 ìF
103 10,000 pF 0.01 ìF
223 22,000 pF 0.022 ìF
473 47,000 pF 0.047 ìF
104 100,000 pF 0.1 ìF
224 220,000 pF 0.22 ìF
474 470,000 pF 0.47 ìF
105 1,000,000 pF 1 ìF
225 2,200,000 pF 2.2 ìF
475 4,700,000 pF 4.7 ìF

 

 

Letter printed capacitor indicate tolerance

Letter Tolerance
A ±0.05 pF
B ±0.1 pF
C ±0.25 pF
D ±0.5 pF
E ±0.5%
F ±1%
G ±2%
H ±3%
J ±5 %
K ±10%
L ±15%
M ±20%
N ±30%
P –0%, + 100%
S –20%, + 50%
W –0%, + 200%
X –20%, + 40%
Z –20%, + 80%

 

 

4.1 Where to Use a Ceramic Capacitor?

 

Ceramic capacitors are applied in a variety of applications. It is primarily used for filtration. It is used in a signal or frequency circuit to filter and purify the signal. It can convert a direct current to a direct current. The ceramic capacitor is a genre of energy storage device. It stores the DC while passing the AC. This is what the ceramic capacitor looks like.

 

 

4.2 How We Read Ceramic Capacitor Value?

 

 

alphabetic code

 

 

The first is an alphabetic code that indicates the component's tolerance. The second is a numeric code that tells us the actual capacitance of the capacitor.

 

So let's take a look at our example right now. In our example, the value is 102 k. The first significant digit in the code is one, and the second significant digit is zero. As a result, these are the numbers in front of our multiplier.

 

 

 

 

How to read the values of Ceramic Capacitors?

 

4.3 Calculate Ceramic Capacitor Value

 

So, if we take your multiplier, which is two, and looks at the chart, that equals two zeros. As a result, we append two zeros to the end of the number. So, picofarad, it's 1000. Now, K represents our component tolerance, which in this case is plus or minus 10%. So that's how we figure out the capacitor's size and rating.

 

Now I'm going to show you how to use a multimeter to measure the capacitance of a capacitor. In this example, I'm using a capacitor with the numerical value 103 written on it, which equals 10-nanofarads.

 

 

 

nine ferrites

 

When you look at the display of what is rated, you'll notice that its practical rating is it works, and it has nine ferrites. So tolerances are around 10%. When you connect it to your actual multimeter, In this one, make sure you have an appropriate terminal. As you can see, I have the capacitance symbol in the bottom right-hand corner. Then, make sure your multimeter is set to the appropriate range. Then double-check that you've selected the correct option.

 

Ceramic disk capacitor codes table

 

Picofarad pF Nanofarad nF Microfarad F Code
10 0.01 0.00001 100
15 0.015 0.000015 150
22 0.022 0.000022 220
33 0.033 0.000033 330
47 0.047 0.000047 470
100 0.1 0.0001 101
120 0.12 0.00012 121
130 0.13 0.00013 131
150 0.15 0.00015 151
180 0.18 0.00018 181
220 0.22 0.00022 221
330 0.33 0.00033 331
470 0.47 0.00047 471
560 0.56 0.00056 561
680 0.68 0.00068 681
750 0.75 0.00075 751
820 0.82 0.00082 821
1000 1 0.001 102
1500 1.5 0.0015 152
2000 2 0.002 202
2200 2.2 0.0022 222
3300 3.3 0.0033 332
4700 4.7 0.0047 472
5000 5 0.005 502
5600 5.6 0.0056 562
10000 10 0.1 102
15000 15 0.015 152
22000 22 0.022 223
33000 33 0.033 333
47000 47 0.047 473
68000 68 0.068 683
100000 100 0.1 104
150000 150 0.15 154
200000 200 0.2 254
220000 220 0.22 224
330000 330 0.33 334
470000 470 0.47 474
680000 680 0.68 684
1000000 1000 1 105
1500000 1500 1.5 154
2000000 2000 2 205
2200000 2200 2.2 225
3300000 3300 3.3 335
4700000 4700 4.7 475

 

The final number written on a ceramic capacitor is the power of ten multiplied by the first two numbers.

If a ceramic capacitor has the code 682, First, look at the last number. So, as we can see, the final number is 2. The multiplier is now 102.

 

4.4 Some Examples

 

204 = 20×104 = 200000 PF

472 = 47×102 = 4700 PF

502 = 50×102 = 5000 PF

330 = 33×100 = 33 PF   [100 = 1]

UNITS

 

1000 nanofarad(nF) = 1 microfarad(µF)

1 picofarad = 10-12farads.

Nano= 10-9

Micro= 10-6

1 Nano Farad= 10-9 Farad

1 Microfarad (µF)= 10-6 Farad

1 nF = 1000 pF

1 pF = 0.001 nF

 

Example:

 

convert 15 nF to pF:

15 nF = 15 × 1000 pF = 15000 pF

 

Capacitor voltage code

 

0G 4VDC 0L 5.5VDC 0J 6.3VDC
1A 10VDC 1C 16VDC 1E 25VDC
1H 50VDC 1J 63VDC 1K 80VDC
2A 100VDC 2Q 110VDC 2B 125VDC
2C 160VDC 2Z 180VDC 2D 200VDC
2P 220VDC 2E 250VDC 2F 315VDC
2V 350VDC 2G 400VDC 2W 450VDC
2H 500VDC 2J 630VDC 3A 1000VDC

 

Ⅴ FAQ

 

1. What is ceramic capacitor used for?
 
Ceramic capacitors are used for all types of circuits in a number of applications. There are four main capacitor applications that are described in detail below: coupling, decoupling, smoothing, and filtering.

 

2. Do ceramic capacitors go bad?
 
Like mica capacitors, ceramic capacitors also very rarely go bad. Do not replace ceramic disc capacitors unless you are sure one has gone bad. ... While replacing the capacitors, check the radio's resistors. Since you will be replacing the capacitors, you should snip one lead of each paper and electrolytic capacitor.

 

3. Why do ceramic capacitors fail?
 
Ceramic capacitors can fail in a couple of ways. They can be mechanically damaged - too much physical stress (pressure on the part or the board is bent a little too much) can cause a crack. The capacitor will then develop short circuits between layers. It acts more like a resistor in that case.
 
 
4. When should you use a capacitor?
 
Capacitors are widely used in electronic circuits for blocking direct current while allowing alternating current to pass. In analog filter networks, they smooth the output of power supplies.
 
5. What is the practical use of capacitor?
 
The most common use for capacitors is energy storage. Additional uses include power conditioning, signal coupling or decoupling, electronic noise filtering, and remote sensing. Because of its varied applications, capacitors are used in a wide range of industries and have become a vital part of everyday life.
 
 
6. Why capacitor is not used as battery?
 
Capacitors don't provide large amount of energy because they have less energy density than batteries. Capacitors are useful to provide short duration power requirements because they can be charged or discharged at a higher rate than the batteries.
 

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