Discovery I (LJ) V8-3.9L (1994)
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The flow of current through a conductor can be compared to traffic on a super highway and on a one-lane street. The more lanes, the more traffic that can
flow. A large conductor can carry a larger current than a smaller one of the same material. It offers less obstruction or "resistance" to the flow of
electrons, due to its size. Conductor size is regulated by S.A.E. standards. This - system assigns "gauge" numbers to certain size wires.
Remember that the wire size increases as the American gauge number decreases. As an example, a sixteen gauge wire can carry less current than a
twelve gauge wire. Metric sizes are larger for larger diameter wires.
WIRE SIZE CONVERSION TABLE
METRIC SIZES
* AWG SIZES
.22
24
.35
22
.50
20
.80
18
1.00
16
2.00
14
3.00
12
5.00
10
8.00
18
13.00
6
19.00
4
32.00
2
* Denotes American Wire Gauge Systems
NOTE: If you are not sure of the wire size, start with the largest opening in your wire stripper and work down until you get a clean strip of the
insulation. Be careful to avoid nicking or cutting any of the wires.
WIRE CURRENT CAPACITY
Conductors follow specific rules in respect to their ability to carry an electrical current.
1. Resistance increases as cross-sectional area decreases.
2. Resistance is directly related to the material from which the conductor is made. Silver conducts better than copper, but copper is better than
aluminum.
3. Resistance goes up as the length of a conductor increases.
4. Resistance in most conductors goes up as the temperature of the conductor goes up.
5. Excessive current can heat a conductor to the point where the insulation will melt and the conductor will burn or melt.
The resistance of a uniform, circular copper wire is dependent upon the length of the wire, cross-sectional area of the wire, and the temperature of the
wire. If the length is doubled, the resistance between the wire ends is doubled. If the cross-sectional area of a wire is doubled, the resistance for any given
length will be cut in half.
An example of the effect of temperature on a section of wire is as follows:
A ten foot length of wire having a resistance of 0.03 ohm at .70 °F will have a resistance of 0.04 ohm at 185 °F, or an increase of thirty-five percent.
BODY WIRING
Solid Wires/Stranded Wires
