2 Properties of Conductors

In the previous Article," Introduction to Conductor Inspection ", I listed all the important terms and their definitions in one complete glossary.


Today, I will explain the different Properties of Conductors as follows.



3- Properties of Conductors 

The fundamental concern of power cable engineering is to transmit current (power) economically and efficiently. The choice of the conductor material, size, and design must take into consideration such items as:

1. Ampacity (current carrying capacity),
2. Voltage stress at the conductor,
3. Voltage regulation,
4. Conductor losses,
5. Bending radius and flexibility,
6. Overall economics,
7. Material considerations,
8. Mechanical properties.

As an Electrical Inspector, you will check to see that conductors are of the proper size, rating, insulation, and terminated correctly.



3.1 Type of Material

Not all materials conduct current equally well. Two materials of interest in electricity are:

1. Conductors: they allow current to flow,
2. Insulators: they oppose the current to flow.

The ease with which a metal allows current to flow is described as conductance. 

Definition Conductance: it is a measure of the ability of a given material to conduct electrical current.

• All metals are given a conductance rating which shows how well they conduct electricity, as compared to copper. The best conductor is silver, but copper is used more often because it is cheaper. Gold is a better conductor than aluminum but once again it is rarely used.

• The type of material used as a conductor will affect its current carrying capacity. This is because different material elements vary in their amount of conductivity or specific resistance.

Definition Specific Resistance: It quantifies how strongly a given material opposes the flow of electrical current. It is the reciprocal of conductance. The specific resistance of a metal (conductor) is based on 1 circular-mil, one foot long.

To compute the resistance of a conductor of any metal, use the value given for the resistance of a circular mil-foot of the material and use the following formula.

Example#1:
If the resistance of 1 cmil-ft of copper at 23C° is 10.5, what is the resistance of 500 feet of copper wire with a diameter of .292?



Solution:

  

Note For rough estimating computations of resistance of round copper wire in ohms per thousand feet, divide 10,500 by the size of the wire in circular mils.

Table-1 is a list of material elements and their specific resistance values. For example, a copper wire will pass more current than an aluminum wire of the same diameter and the same length. The copper wire has a lower specific resistance value.

Table-1: Specific resistances of conducting elements.(Resistance equals 1 cir-mil-ft in ohms)

3.2 Copper VS Aluminum Conductors

• Although silver is the best conductor, its cost limits its use to special circuits. Silver is used where a substance with high conductivity or low resistivity is needed. 

• The two most commonly used conductors are copper and aluminum. Each has positive and negative characteristics that affect its use under varying circumstances. A comparison of some of the characteristics of copper and aluminum is given in Table-2. 

Characteristics	Copper	Aluminum
Tensile strength (lb/in2)	55,000	25,000
Tensile strength for same conductivity (lb)	55,000	40,000
Weight for same conductivity (lb)	100	48
Cross section for same conductivity (C.M.)	100	160

Table-2: Comparative Characteristics of Copper and Aluminum

• Copper has a higher conductivity than aluminum. It is more ductile (can be drawn out). Copper has relatively high tensile strength (the greatest stress a substance can bear along its length without tearing apart). It can also be easily soldered. However, copper is more expensive and heavier than aluminum. 

• Although aluminum has only about 60 percent of the conductivity of copper, its lightness makes long spans possible. Its relatively large diameter for a given conductivity reduces corona. Corona is the discharge of electricity from the wire when it has a high potential. The discharge is greater when smaller diameter wire is used than when larger diameter wire is used. However, the relatively large size of aluminum for a given conductance does not permit the economical use of an insulation covering. 

• The choice between copper and aluminum conductors should carefully compare the properties of the two metals, as each has advantages that outweigh the other under certain conditions. 

The properties most important to the cable designer are:



A- DC Resistance

The conductivity of aluminum is about 6 1.2 to 62 percent that of copper. Therefore, an aluminum conductor must have a cross-sectional area about 1.6 times that of a copper conductor to have the equivalent dc resistance. This difference in area is approximately equal to two AWG sizes.



B- Weight

• One of the most important advantages of aluminum, other than economics, is its low density. A unit length of bare aluminum wire weighs only 48 percent as much as the same length of copper wire having an equivalent dc resistance.

• However, some of this weight advantage is lost when the conductor is insulated, because more insulation volume is required over the equivalent aluminum wire to cover the greater circumference.

C- Ampacity

The ampacity of aluminum versus copper conductors can be compared by the use of many documents. See Chapter 9 for details and references, but obviously more aluminum cross-sectional area is required to carry the same current as a copper conductor as can be seen from Table-1.



D- Voltage Regulation

• In ac circuits having small (up to #2/0 AWG) conductors, and in all dc circuits, the effect of reactance is negligible. Equivalent voltage drops result with an aluminum conductor that has about 1.6 times the cross-sectional area of a copper conductor.

• In ac circuits having larger conductors, however, skin and proximity effects influence the resistance value (ac to dc ratio, later written as ac/dc ratio), and the effect of reactance becomes important. Under these conditions, the conversion factor drops slightly, reaching a value of approximately 1.4.

E- Short Circuits

Give consideration to possible short circuit conditions, since copper conductors have higher capabilities in short circuit operation.



F- Other Important Factors

• Additional care must be taken when making connections with aluminum conductors. Not only do they tend to creep, but they also oxidize rapidly. When aluminum is exposed to air, a thin, corrosion-resistant, high dielectric strength film quickly forms.

• When copper and aluminum conductors are connected together, special techniques are required in order to make a satisfactory connection. 

• Aluminum is not used extensively in generating station, substation, or portable cables because the lower bending life of small strands of aluminum does not always meet the mechanical requirements of those cables. However, it is the overwhelming choice for aerial conductors because of its high conductivity to weight ratio and for underground distribution for economy where space is not a consideration.

• Economics of the cost of the two metals must, of course, be considered, but always weighed after the cost of the overlying materials.

In the next Article, I will explain the Size Measurement Units of conductors. Please keep following.

Back To Course CAB-1: Inspect Conductors

2 Introduction to Fluorescent and Incandescent Light Fixtures Inspection

1- Introduction


In this course you will learn:

• How to inspect fluorescent lighting fixtures and incandescent lighting fixtures (Fig.1),

• How to identify the correct fixture to be inspected,

• How to verify that the fixture is properly installed,

• How to document your inspection results.

This course will reference the National Electric Code (NEC) and Underwriters Laboratory (UL) documents.

Fig.1: Fluorescent and Incandescent Lighting Fixtures

2- Verify that the Correct Fixture is being inspected


First: Incandescent Light Fixtures

• The incandescent lamp consists of a filament which is a highly refractory conductor mounted in a transparent or translucent glass bulb and provided with a suitable electrically connecting base. The filament is heated by the passage of an electric current through it to such a high temperature that it becomes incandescent and emits light. The older types of bulbs had the air inside of them removed. The modern lamps today have this space filled with an inert transparent gas such as nitrogen.

• (Fig.2) shows porcelain, single lamp, incandescent light fixture and a lamp. When the lamp is attached, the fixture operates as a common unit. The incandescent light fixture can be designed to hold one of several types of lamps. This type of fixture is used with a screw—type lamp base or cap. 

Fig.2: A Standard Incandescent Light Fixture and a Lamp

• The incandescent lamp is widely used in many applications and often seen in the home. The life expectancy of an incandescent lamp is much less than a fluorescent lamp. The incandescent lamp is identified by the filament. The filament is made from a metallic material called tungsten. (Fig.3) shows a heavy duty lamp used for construction work.

Fig.3: Basic Construction of a Standard Incandescent Lamp

Classification of incandescent Lamps Incandescent lamps can be classified in six different ways, according to: The class of lamp, The type of the base, The shape of the bulb, The type of filament, The finish of the bulb, The type of service.

1- Class of lamp Lamps are classified as either Type B or Type C.  The Type B lamp is one in which all the air has been removed.  The Type C is one which is gas-filled. Gas-filled lamps are the most widely used types.

2- The type of base A number of different types of bases for incandescent lamps are in use (fig.4). Fig.4: Standard Incandescent Lamp Bases The medium base, used on general-service lamps of 300 watts and less, is the most common type.  The mogul base is used for 300 watts and above.   Other popular bases are the bayonet, candelabra, and intermediate bases are used on small size (miniature) lamps.

3- Shape of bulb Incandescent lamps come in various shapes and sizes (fig.5), all designated by a letter or letters followed by a number. The letter is to identify the lamp's shape while the numerical designation is to identify the diameter of the lamp in an eighth of an inch.  Fig.5: Standard Incandescent Lamp Shapes Example:  Lamp model 60A19, means : 60: Wattage (60 W)  A: Bulb shape  19: Maximum bulb diameter, in eighths of an inch. (19 ÷ 8 = 2.38 in) The most common shape for incandescent lamps and the one everyone knows is the A shape (A-19) - The A is only an arbitrary designation.  The below table include the most used shape codes for Incandescent lamps. Code Name Use A Arbitrary (standard) universal use for home lighting B Bullet decorative BR Bulging reflector for substitution of incandescent R lamps C Cone shape used mostly for small appliances and indicator lamps ER Elliptical reflector for substitution of incandescent R lamps F Flame decorative interior lighting G Globe ornamental lighting and some floodlights P Pear standard for streetcar and locomotive headlights PAR Parabolic aluminized used in spotlight and floodlight reflector S Straight lower wattage lamps - sign and decorative T Tubular showcase and appliance lighting

4- Bulb finishes Incandescent bulbs can be finished in a variety of different ways. Some of the more popular ones are listed below: Clear, Inside-colored, Inside-frosted, Outside-colored, Silvered bowl, Colored-glass, White, Outside-coating, Daylight.

5- Type of filament Several different types of filament structures are used (fig.6). The filament structure is designated by a letter or letters to indicate whether the wire is straight or coiled and by an arbitrary number sometimes followed by a letter to indicate the arrangement of the filament on the supports. Prefix letters include: S =    straight; wire is straight or slightly corrugated C =    coil; wire is wound into a helical coil or it may be deeply fluted. CC = Coiled coils; wire is wound into a helical coil, and this coil wire is again wound into a helical coil. Fig.6: Standard Incandescent Lamp Filaments  The below table include the most Common Filament types for Incandescent lamps. Designation Description C-2F  Short, coiled filament requiring two supports. C-2R  Short, coiled curbed filament requiring no support. C-2V  Short, coiled filament requiring support. CC-2V  Short, double-coiled filament requiring support. C-5  Concentrated filament for small light sources. C-6  Short, coiled filament requiring little or no support. CC-6  Short, double-coiled filament requiring few supports. 2C-6  Two short, coiled filaments requiring little or no support mounted one on top of the other. C-7  Long filament supported at the top for base up usage. C-7A  Long filament supported at the top and at the base for universal usage. C-8  Coiled filament mounted in lamp axis. Can be extended like Lumiline lamps. CC-8  Short, double-coiled filament mounted in the lamp axis. 2CC-8  Two short, double-coiled filaments mounted in the lamp axis. C-9  Average length filament mounted in the lamp axis. CC-9  Average length double-coiled filament mounted in the lamp axis. C-11  Average length, concentrated filament. Well supported, "M" Shape. C-13  Flat, very concentrated filament for projection equipment. CC-13  Flat, very concentrated double-coiled filament for projection equipment. C-17  Long filament requiring more support than usual.

6- Type of service Incandescent bulbs are manufactured for a wide range of services, most of which can be classified into three categories: General lighting service: These are the most common bulbs used   for general lighting. Special lighting service: This group includes the three-way bulbs, daylight lamps, and decorative lamps. Miscellaneous lighting service: Street lighting, traffic-signal lamps,            and photographic lamps fall into this category. The overhead projector lamp is also included in this group.

In the next Article, I will explain Fluorescent Lighting Fixtures and its Components. Please keep following,

Back To Course LG-1: Inspect Fluorescent / Incandescent Light Fixtures