Magnetism Is One of the Fundamental Forces- Like Gravity and Electricity

Chapter 4

Electromagnetism

Magnetism:

Magnetism is one of the fundamental forces- like gravity and electricity.

Materials that have the ability to attract iron are classified as having a strong magnetic force.

When a charged particle is in motion, a magnetic force field perpendicular to the motion will be created.

Orbital spin moment: the magnetic effect created by electrons orbiting around a nucleus in an atom.

The closed loop of the orbit cancels out all but the field that is perpendicular to the plane of the motion.

Spin magnetic moment: the magnetic effect created by electrons spinning on their axes.

The disruption of this axial spinning and the energy released as it reorients itself are the physical basis that permits magnetic resonance imaging.

Atoms having a significant number of electrons with their magnetic moments in the same direction (magnetic dipole/magnetic domain), especially when the outer shells are involved, will exhibit a net magnetic field in a distinct direction.

If an external force has the time or strength to orient enough of the dipoles in the same direction and/or cause those dipoles to grow in size, the object exhibits a uniformly strong magnetic field and referred as a magnet.

The force fields created when magnetic dipoles orient to create a magnet are called lines of force, lined of flux, or the magnetic field.

The stronger the magnetic field, the more lines of flux.

The ends of a magnet are defined as the north and south poles: lines of force always flow from north to south outside a magnet and from south to north within a magnet; these lines of force never intersect.

The stronger the magnetic field, the greater the number of lines of flux or the greater the flux density.

Flux density is determined by field strength and by the area in which the lined of flux are located.

Magnetic flux = field strength / area

The SI unit for magnetic flux is the Weber. 1 Weber = 108 lines of flux.

The units for flux density are the tesla (1 T = 1 Wb/m2) and the gauss (1 tesla = 10,000 gauss)

Earth: 0.0001 T

Household magnet: 0.1 T

MRI equipment: 0.3 – 2.0 T

Magnets: classification by production

Natural magnets are created when iron oxide (magnetite) remains in the earth’s magnetic field for ages, slowly orienting the magnetic dipoles in the same direction (called lodestones).

Artificial permanent magnets are manufactured from a steel alloy called alnico, composed of aluminum, nickel and cobalt. While it is hot, alnico is subjected to the field of a strong commercial magnet to permit easier orientation of the magnetic dipoles. Upon cooling, becomes permanent. Can be destroyed by heat or abrupt physical injury- causes the magnetic alignment to become random again, losing the magnetic fields.

Electromagnets are temporary magnets produced by moving electric current.

Any flow of current produces a magnetic field. When the current ceases flowing, the magnetic field collapses, the magnetic field is proportional to the electric current: more current = stronger magnetic field.

Laws governing magnetism:

1. Repulsion / attraction: like poles repel; unlike poles attract, like lines of force repel; and unlike lines of force attract.
2. Inverse square law: the force between two magnetic fields is directly proportional to the product of their magnitudes and inversely proportional to the square of the distance between them.
3. Magnetic poles: every magnet has two poles, a north and a south, dividing the magnet just make smaller magnets, and it does not affect its strength.

Magnetic induction: when a nonmagnetized iron bar is brought within the lines of force of a strong magnet, the dipoles will temporarily align themselves with the lines of force passing through the iron bar (soft iron works best).

Temporary- only magnetic during magnetic induction

Magnetic sinks: shielding is accomplished by providing a highly ferromagnetic material, such as iron, through which stray magnetic fields can be directed.

Permeability: the ease with which a material can be magnetized.

Retentivity: is the ability of a material to stay magnetized.

Magnets- classification by reaction to a magnetic field:

1. Ferromagnetic: highly permeable and greatly susceptible to induction, majority of dipoles in same direction, the material must permit the atoms to be oriented on the same direction. (iron, cobalt and nickel)
2. Paramagnetic: have low permeability and weak attraction to magnetic fields, slight majority of dipoles in same direction (platinum, aluminum, MRI contrast material)
3. Diamagnetic: are weakly repelled by all magnetic fields (beryllium, bismuth, lead and water)
4. Nonmagnetic: not affected by magnetic fields and cannot be magnetized, most often composed of atoms locked into crystalline or molecular patterns, elimination the ability of electrons to freely orient themselves to external magnetic lines of force (wood, glass, rubber, plastic, most materials).

Electromagnetism:

Electricity and magnetism are actually different aspects of the same force, electromagnetism.

Hans Oersted (1777 – 1851)

Observed the deflection of a compass during a classroom experiment

When there is no current flowing in the wire, the compass needle aligns itself with the earth’s magnetic field

When current is flowing, the needle is deflected toward the wire

Any moving current produces a magnetic fields, a charge at rest has no magnetic field

John Fleming (1849 – 1945)

Hand rules to describe the relationships between electricity and magnetism

Right hand thumb rule: if the right hand is used to grasp a conducting wire with the thumb in the direction of the current flow, the fingers will indicate the direction of the magnetic field lines of force surrounding the conductor.

Solenoids and electromagnets:

Solenoid; a coil consisting of a series of loops, which serve to increase the flux density; inside the loop the magnetic fields from both sides join to double the magnetic flux density.

Electromagnet: temporary magnet by moving electric current, the flux density is increased further by adding a ferromagnetic core to a solenoid.

The strength is determined by:

The number of loops or turns of wire

The current strength

The permeability of the core

Both the solenoid and the electromagnet demonstrate magnetic properties only while electric current is flowing.

The effectiveness of solenoids and electromagnets:

Diameter of the coil

Its length

The current passing along the coil

Electromagnetic induction:

Michael Faraday (1791 – 1867) discovered that the simple presence of a magnetic field is not sufficient to cause electrons to move along a wire, the magnetic lines of force and the wire must have a motion relative to each other to induce electric current.

1. Move the conductor through a stationary unchanging magnetic field
2. Move the magnetic lines of force through a stationary conductor with an unchanging strength magnetic field
3. Vary the magnetic flux strength from a stationary magnet through a stationary conductor, lines of force will contract and expand causing the motion necessary to induce current.

The First law of Electromagnetics (Faraday’s Law): states that four factors regulate the strength of induced current when magnetic lines of force and a conductor arein motion relative to one another

1. The strength of the magnetic field
2. The speed of the motion between the lines of force and the conductor
3. The angle between the magnetic lines of force and the conductor and
4. The number of turns in the conduction coil

The Second law of Electromagnetics (Lenz’s Law): states that induced current flow sets up a magnetic field opposing the action that produced the original current, that induced current opposes any flux change. Determines the direction of the induced current.

The First and Second Laws of induction of current by magnetic fields apply to both forms of induction: mutual and self induction.

Mutual induction: occurs when two coils are placed in proximity and a carrying current supplied to the first coil induces a similar flow in the second coil, the flow occurs in the secondary coil because the primary current alternates (moving lines of force from a varying intensity current will induce electron flow in the wire through which it passes).

Self-induction: the ability of an alternating current to switch directions, causing an opposing potential difference to induce against the incoming supply of electrons; allows direct current to flow while at the same time hindering alternating current.

A coil supplied with alternating current permits a steady flow of electrons and establishes an electromagnetic effect for half the cycle, when current supply reverses, the previously established electromagnetic north and south poles will induce an opposing potential difference, attempting to induce against the incoming supply of electrons (inductive reactance)

Components of the x-ray tube

Electric generator – mechanical motion produces electricity

Electric motor – electricity produces mechanical motion

Transformer – alternates current and voltage from one side to the other

Generators

Generator (dynamo) is a device that converts mechanical energy to electrical energy (moving lines of flux in relation to a conductor to induce current)

A simple generator is composed of a conductor and magnets. The conductor is a coil of wire (armature), set between opposing magnetic poles so that it encounters the strongest lines of force. Because the armature is moving in the magnetic field, a current is produced.

A set of slip rings and brushes permits the circuit to remain stationary while the armature rotates without breaking the electrical contact between them. Each slip ring connects to one end of the armature wire. This allows the electrons to flow without interruption.

Alternating current: produced when the wires motion relative to the lines of force is reversed.

A direct current generator- made by exchanging the slip rings for a commutator ring, a single ring that is divided in half, with each half connected to one end of the armature wire.

The commutator ring changes the brushes with which it is in contact with, reversing the exiting connections, thus keeping the current flow in the circuit flowing in the same direction. It is at this point that direct current is produced.

Motors

Motors: a device supplied with electrical current to produce mechanical motion.

The motor principle is a result of the interaction of magnetic fields when an electric current is sent along a conductor that is residing in a magnetic field. As current flows through the conducting coil, a magnetic field is established, because the conducting coil lies within the lined of force from the stationary magnets, the induced lines of force will be attracted in one direction while at the same time being repelled in the other direction.

The net result is that the conductor begins to move.

The magnetic field of the conductor would be either

• Attracted to the external field if the external lines of force were opposing directions
• Repelled by the external magnetic field lines of force if the lines of force were in the same direction

Synchronous alternating current motors have conducting coils that turn at the same speed as the generator armature supplying the current (used in turning devices).

Alternating current induction motors

Used in somex-ray tubes with rotating anodes to prevent overheating

Utilize a rotor coil- consist of bars of copper around an iron core with the exterior magnetic field supplied by several pairs of electromagnets

• Called a stator which mist be supplied with multiphase current which activates the next pair of electromagnets causing the rotor to turn to align itself with the magnetic force

Thus producing a strong magnetic field, increasing the power of the motor and permitting it to run at any speed

When a meter is connected in series, it measures current in amperes and called an ammeter.

When a meter is connected in parallel, it measures voltage in volts and called an voltmeter.

Controlling electrical current

Transformers transform electrical current and potential (voltage) into either higher or lower intensities; are composed of two coils placed near one another. If current is supplied to one coil, the lines of force that are induced will pass through the other coil and induce a flow of electrons. Transformers are used to change voltage and to control electrical current.

The coil that is supplied with current is the primary.

The coil in which current is induced is the secondary.

Instead of the electromagnet having ends, it is an enclosed loop, which keeps the magnetic field confined to the core. The primary core is wrapped around one side, the secondary coil the opposite side. Alternating current necessary because AC causes the magnetic fields to change.

When the voltage is increased from primary to secondary, it is called a step up transformer (more turns in coil of secondary coil). A step-up transformer increases voltage from primary to secondary while decreasing amperage.

When the voltage is decreased from primary to secondary, it is called a step down transformer (less turns in coil of secondary coil). A step-down transformer decreases voltage from primary to secondary while increasing amperage.

All transformers must operate on alternating current to provide the establishing and collapsing magnetic fields that induce voltage changes in the secondary coil.

The transformer Law:

Vs / Vp = Ns / Np

Where:

V = potential difference in volts

N = number of turns of wire in the coil

P = primary coil

S = secondary coil

Voltage and number of turns are directly proportional, while voltage and amperage are inversely proportional. The number of turns and amperage is inversely proportional.

Is / Ip = Vp / Vs

Is / Ip = Np / Ns

Air core transformers: arrangement of two coils of wire in proximity to facilitate induction, no iron core.

Open core transformers: arrangement of two coils of wire each filled with an iron core in proximity to facilitate induction.

Closed core transformers: arrangement of two coils of wire each filled with an iron core in proximity to facilitate induction that converges the inside and outside lines of force through the core.

Autotransformer: a transformer that automatically sets up by adjustments.

The autotransformer is used to vary the incoming line voltage to an appropriate level for the high voltage step up transformer (small changes in voltage or current).

The high voltage step up transformer is used to raise the incoming line voltage to the 5 – 15 volt range and 3 – 5 ampere range used to heat the x-ray tube filament.

A capacitor is a device capable of accumulating and storing an electrical charge. A simple capacitor consists of two insulated metal plates with opposite charges. The repulsion between the charges in the two plates permits a greater number of electrons to be stored on each.

The capacitor will accept a charge until it equals the DC voltage. When discharged the capacitor has the ability to deliver the stored charge in short and easily controlled intervals.

Dielectric: the insulation between the plates.

Rectification

X-ray tubes work best when receiving direct current.

Rectification is the process by which alternating current is changed to pulsating direct current. Creates electrical one-way streets by permitting electrons to flow easily in one direction while offering a high resistance to movement in the other direction.

Electrons flow only in one direction – cathode to anode

It cant reverse from anode to cathode

Tubes called diodes or solid-state silicon tubes are used today instead of valve tubes

Half-wave rectification: suppressed rectification from only half of the incoming alternating current being converted to pulsating direct current. The supply of alternating current to a rectifier results in pulsating direct current. Danger of this type of rectification is over heating and thermionic emission of the anode, which would break the filament.

Full-wave rectification: the conversion of the opposing half of the incoming electron flow to always move in the same direction, instead of discarding half the cycle.

Uses four diodes in a high voltage circuit

• Diodes change negative current into positive current

Allows exposure times to be cut in half

4 rectifiers used in a full wave rectification circuit