Generator

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Working Principle And Use Of Generator

 

Generator is a machine that converts mechanical energy into electrical energy. It works based on principle of faraday law of electromagnetic induction. The faradays law states that whenever a conductor is placed in a varying Magnetic Field, EMF is induced and this induced EMF is equal to the rate of change of flux linkages. This EMF can be generated when there is either relative space or relative time variation between the conductor and magnetic field.

An electric conductor moves through a magnetic field, the Magnetism will interface with the electrons in the conductor to induce a flow of electrical current inside it.


Working of Generators:

Generators are basically coils of electric Conductors, normally copper wire, that are tightly wound onto a Metal core and are mounted to turn around inside an exhibit of large magnets. An electric conductor moves through a magnetic field, the magnetism will interface with the electrons in the conductor to induce a flow of electrical current inside it.

The conductor coil and its core are called the armature, connecting the armature to the shaft of a mechanical power source, for example an motor, the copper conductor can turn at exceptionally increased speed over the magnetic field.

 

The point when the generator armature first starts to turn, then there is a weak magnetic field in the iron pole shoes. As the armature turns, it starts to raise voltage. Some of this voltage is making on the field windings through the generator regulator. This impressed voltage builds up stronger winding current, raises the strength of the magnetic field. The expanded field produces more voltage in the armature. This, in turn, make more current in the field windings, with a resultant higher armature voltage. At this time the signs of the shoes depended on the direction of flow of current in the field winding. The opposite signs will give current to flow in wrong direction.

 


Types of Generators:

The generators are classified into types.

  • AC generators
  • DC generators

 


AC Generators:

These are also called as alternators. It is the most important means of producing electrical power in many of the places since now days all the consumers are using AC. It works based on principle of the electromagnetic induction. These are of two types one is induction generator and other one is synchronous generator. The induction generator requires no separate DC excitation, regulator controls, frequency control or governor. This concept takes place when conductor coils turn in a magnetic field actuating a current and a voltage. The generators should run at a consistent speed to convey a stable AC voltage, even no load is accessible.

Synchronous generators are large size generators mainly used in power Plants. These may be rotating field type or rotating armature type. In rotating armature type, armature is at rotor and field is at stator. Rotor armature current is taken through slip rings and brushes. These are limited due to high wind losses. These are used for low power output applications. Rotating field type of alternator is widely used because of high power generation capability and absence of slip rings and brushes.

 


Advantages of AC Generator:

  • These Generators are generally maintenance free, because of absence of brushes.
  • Easily step up and step down through transformers.
  • Transmission link size might be thinner because of step up feature
  • Size of the generator relatively smaller than DC machine
  • Losses are relatively less than DC machine
  • These Generator breakers are relatively smaller than DC breakers

 


DC Generators:

DC generator is typically found in off-grid applications. These generators give a seamless power supply directly into electric storage devices and DC power grids without novel equipment. The stored power is carries to loads through dc-ac converters. The DC generators could be controlled back to an unmoving speed as batteries tend to be stimulating to recover considerably more fuel.


Classification of DC Generators

D.C Generators are classified according to the way their magnetic field is developed in the stator of the machine.

  • permanent-magnet DC generators
  • Separately-excite DC generators and
  • Self-excited DC generators.

 

Permanent magnet DC generators do not require external field excitation because it has permanent magnets to produce the flux. These are used for low power applications like dynamos. Separately-excite DC generators requires external field excitation to produce the magnetic flux. We can also vary the excitation to get variable output power. These are used in electro plating and electro refining applications. Due to residual magnetism present in the poles of the stator self-excited DC generators can able to produce their own magnetic field ones it is started. These are simple in design and no need to have the external circuit to vary the field excitation. Again these self-excited DC generators are classified into shunt, series, and compound generators.

These are used in applications like battery charging, welding, ordinary lightening applications etc.


Advantages of DC Generator:

  • Mainly DC machines have the wide variety of operating characteristics which can be obtained by selection of the method of excitation of the field windings.
  • The output voltage can be smoothed by regularly arranging the coils around the armature .This leads to less fluctuations which is desirable for some steady state applications.
  • No shielding need for radiation so cable cost will be less as compared to AC.

 


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A generator is a device that converts mechanical energy into electrical energy. The most common type of generator is an alternating current (AC) generator, which produces an alternating current (AC) output. AC generators are used in a variety of applications, including power generation, welding, and motor drives.

An alternator is a type of AC generator that uses a rotating magnetic field to induce an AC voltage in a stator winding. The rotating magnetic field is created by a rotor that is either driven by a prime mover, such as an engine or turbine, or by an Electric motor.

An arc generator is a type of generator that produces an electric arc. Arc generators are used in a variety of applications, including welding, cutting, and lighting.

A brushless generator is a type of AC generator that does not use brushes. Brushless generators are more efficient than generators that use brushes, and they are also more reliable.

A capacitor-start generator is a type of AC generator that uses a capacitor to start the motor. Capacitor-start generators are used in a variety of applications, including power generation, welding, and motor drives.

A commutator generator is a type of DC generator that uses a commutator to convert the AC output of the generator into DC output. Commutator generators are used in a variety of applications, including power generation, welding, and motor drives.

A DC generator is a type of generator that produces a direct current (DC) output. DC generators are used in a variety of applications, including power generation, welding, and motor drives.

An engine-driven generator is a type of generator that is driven by an engine. Engine-driven generators are used in a variety of applications, including power generation, welding, and motor drives.

A generator set is a combination of a generator and an engine. Generator sets are used in a variety of applications, including power generation, welding, and motor drives.

An induction generator is a type of AC generator that uses an induction motor to produce an AC output. Induction generators are used in a variety of applications, including power generation, welding, and motor drives.

An inverter generator is a type of generator that uses an inverter to convert the DC output of the generator into AC output. Inverter generators are used in a variety of applications, including power generation, welding, and motor drives.

A permanent magnet generator is a type of DC generator that uses permanent magnets to produce a DC output. Permanent magnet generators are used in a variety of applications, including power generation, welding, and motor drives.

A self-excited generator is a type of DC generator that does not require an external source of power to excite the field winding. Self-excited generators are used in a variety of applications, including power generation, welding, and motor drives.

A synchronous generator is a type of AC generator that has a rotating magnetic field that is synchronized with the AC output of the generator. Synchronous generators are used in a variety of applications, including power generation, welding, and motor drives.

An uninterruptible power supply (UPS) generator is a type of generator that is used to provide backup power in the event of a power outage. UPS generators are used in a variety of applications, including data centers, hospitals, and financial institutions.

A variable-speed generator is a type of generator that can vary its output speed. Variable-speed generators are used in a variety of applications, including power generation, welding, and motor drives.

Generators are an essential part of our modern world. They provide us with the electricity that we need to power our homes, businesses, and industries. Generators are also used in a variety of other applications, such as welding, cutting, and lighting.

What is a generator?

A generator is a machine that converts mechanical energy into electrical energy.

How does a generator work?

A generator works by using a magnetic field to induce an electric current in a conductor.

What are the different types of generators?

There are many different types of generators, but the most common are:

What are the advantages of using a generator?

There are many advantages to using a generator, including:

What are the disadvantages of using a generator?

There are a few disadvantages to using a generator, including:

How do I choose the right generator for my needs?

When choosing a generator, you need to consider the following factors:

How do I install a generator?

Installing a generator can be a complex process, and it is important to follow the manufacturer’s instructions carefully. If you are not comfortable installing a generator yourself, you should hire a qualified electrician.

How do I maintain a generator?

Generators require regular maintenance to ensure that they are in good working condition. The frequency of maintenance will depend on the type of generator, the amount of use it receives, and the Environment in which it is used.

What are the safety precautions I should take when using a generator?

When using a generator, it is important to take the following safety precautions:

What are the common problems with generators?

The most common problems with generators include:

How do I troubleshoot common generator problems?

If you are having problems with your generator, you can try the following troubleshooting steps:

Where can I get more information about generators?

You can get more information about generators from the following sources:

Sure, here are some multiple choice questions about the topics of electricity, magnetism, and electromagnetism:

  1. Which of the following is not a type of electric charge?
    (A) Positive charge
    (B) Negative charge
    (C) Neutral charge
    (D) Static charge

  2. Which of the following is not a property of magnets?
    (A) Attraction to iron
    (B) Repulsion to other magnets
    (C) Ability to create an electric field
    (D) Ability to create a magnetic field

  3. Which of the following is not a way to create an electric current?
    (A) Friction
    (B) Chemical Reaction
    (C) Light
    (D) Heat

  4. Which of the following is not a way to create a magnetic field?
    (A) Electric current
    (B) Moving charges
    (C) Permanent magnets
    (D) Static charges

  5. Which of the following is not a property of electromagnets?
    (A) Attraction to iron
    (B) Repulsion to other magnets
    (C) Ability to create an electric field
    (D) Ability to create a magnetic field that can be turned on and off

  6. Which of the following is not a way to use electromagnets?
    (A) In motors
    (B) In generators
    (C) In loudspeakers
    (D) In refrigerators

  7. Which of the following is not a way to generate electricity?
    (A) Using a turbine to turn a generator
    (B) Using a solar panel to create a current
    (C) Using a wind turbine to turn a generator
    (D) Using a generator to create a current

  8. Which of the following is not a way to use electricity?
    (A) To power lights
    (B) To power motors
    (C) To power computers
    (D) To power refrigerators

  9. Which of the following is not a way to use magnetism?
    (A) In compasses
    (B) In refrigerator magnets
    (C) In loudspeakers
    (D) In motors

  10. Which of the following is not a way to use electromagnetism?
    (A) In motors
    (B) In generators
    (C) In loudspeakers
    (D) In refrigerators

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