Difference between revisions of "901.12 Electrical Components"
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Since the resistance of a wire conductor is inversely proportional to the cross-sectional area of the wire, increased voltage drops are developed as the wire diameters decrease. | Since the resistance of a wire conductor is inversely proportional to the cross-sectional area of the wire, increased voltage drops are developed as the wire diameters decrease. | ||
− | The areas of wires in circular mils (mm<sup>2</sup>) and the resistance in ohms per 1000 ft. (1000 m) to be used in calculations are shown in | + | The areas of wires in circular mils (mm<sup>2</sup>) and the resistance in ohms per 1000 ft. (1000 m) to be used in calculations are shown in [[902.15_Designing_a_Traffic_Signal#902.15.6.2_Power_Cable|902.15.6.2 Power Cable]]. The voltage drop in any line is calculated from the formula: |
− | + | : ENGLISH | |
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− | + | : <math>Volts\; drop=\frac{Distance\;(ft) \times \ Amperes \times \ 25}{Area\;(circular\;mils)}</math> | |
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− | + | : METRIC | |
− | + | : <math>Volts\; drop=\frac{Distance\;(m) \times \ Amperes \times \ 0.04125}{Area\;(mm^2)}</math> | |
− | + | Transposing this formula, the required area in circular mils (mm<sup>2</sup>) can be computed: | |
− | |||
− | + | : ENGLISH | |
− | + | : <math>Area\; in\; circular\; mils=\frac{Distance \times \ Amperes \times \ 25}{Permissible\;voltage\; drop}</math> | |
− | + | ||
+ | : METRIC | ||
+ | |||
+ | : <math>Area\; in\; mm^2=\frac{Distance \times \ Amperes \times \ 0.04125}{Permissible\;voltage\; drop}</math> | ||
With the constant wattage ballast, the permissible voltage drop is five percent of the system voltage. A factor of 0.95 is to be applied to the system voltage to allow for line fluctuations. This results in an allowable drop of 23 volts for a 480-volt circuit, and 11 volts for a 240-volt circuit. | With the constant wattage ballast, the permissible voltage drop is five percent of the system voltage. A factor of 0.95 is to be applied to the system voltage to allow for line fluctuations. This results in an allowable drop of 23 volts for a 480-volt circuit, and 11 volts for a 240-volt circuit. | ||
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* High Mast Light Poles - #2 AWG (35 mm<sup>2</sup>) MAXIMUM | * High Mast Light Poles - #2 AWG (35 mm<sup>2</sup>) MAXIMUM | ||
− | If circuit loading or voltage drop requires a larger wire size than the maximum then one or more of the following can be considered: | + | If circuit loading or voltage drop requires a larger wire size than the maximum, then one or more of the following can be considered: |
* Increase the system voltage from 240 volts to 480 volts. | * Increase the system voltage from 240 volts to 480 volts. | ||
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'''901.12.1.2 Example to Determine Necessary Wire Cable Size''' | '''901.12.1.2 Example to Determine Necessary Wire Cable Size''' | ||
− | Given: Five | + | Given: Five LED-B luminaires on a 480-volt circuit at 1200, 1700, 3700, 4300 and 4600 ft. (350, 500, 1100, 1300 and 1400 m), respectively, from the control station. |
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− | + | There must be sufficient current to operate the first luminaries as well as the next four luminaires, etc. Operating current is obtained from the manufacturer of the luminaire. For our example we will assume 0.71 amps. | |
It is also necessary to add 5% to the wire length to allow for snaking. | It is also necessary to add 5% to the wire length to allow for snaking. | ||
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ENGLISH | ENGLISH | ||
− | 1200 ft x 1.05 x 5 | + | 1200 ft x 1.05 x 5 luminaires x 0.71 amps x 25/23 (Permissible Drop) = 4862 cir. mils to 1st luminaire |
− | 500 ft x 1.05 x 4 | + | 500 ft x 1.05 x 4 luminaires x 0.71 x 25/23 = 1621 cir. mils to 2nd luminaire |
− | 2000 ft x 1.05 x 3 | + | 2000 ft x 1.05 x 3 luminaires x 0.71 x 25/23 = 4862 cir. mils to 3rd luminaire |
− | 600 ft x 1.05 x 2 | + | 600 ft x 1.05 x 2 luminaires x 0.71 x 25/23 = 972 cir. mils to 4th luminaire |
− | 300 ft x 1.05 x 1 | + | 300 ft x 1.05 x 1 luminaire x 0.71 x 25/23 = 243 cir. mils to 5th luminaire |
− | + | ::: Total Area = 12,560 cir. mils. | |
METRIC | METRIC | ||
− | 350 m x 1.05 x 5 | + | 350 m x 1.05 x 5 luminaires x 0.71 amps x 0.04125/23 (Permissible Drop) = 2.34 mm<sup>2</sup> to 1st luminaire |
− | 150 m x 1.05 x 4 | + | 150 m x 1.05 x 4 luminaires x 0.71 x 0.04125/23 = 0.80 mm<sup>2</sup> to 2nd luminaire |
− | 600 m x 1.05 x 3 | + | 600 m x 1.05 x 3 luminaires x 0.71 x 0.04125/23 = 2.41 mm<sup>2</sup> to 3rd luminaire |
− | 200 m x 1.05 x 2 | + | 200 m x 1.05 x 2 luminaires x 0.71 x 0.04125/23 = 0.54 mm<sup>2</sup> to 4th luminaire |
− | 100 m x 1.05 x 1 | + | 100 m x 1.05 x 1 luminaires x 0.71 x 0.04125/23 = 0.13 mm<sup>2</sup> to 5th luminaire |
− | + | ::: Total Area = 6.22 mm<sup>2</sup>. | |
− | The wire size is that with the area next above, as shown in Table | + | The wire size is that with the area next above, as shown in [[902.15_Designing_a_Traffic_Signal#Table_902.15.6.2.1_Properties_for_Conductors|Table 902.15.6.2.1 Properties for Conductors]] or #8 AWG (10 mm<sup>2</sup>) (The minimum size used in cable-conduit is #8 AWG (10 mm<sup>2</sup>)). When several circuits are carried from one control station, determine the wire size for each circuit separately. #10 AWG (6 mm<sup>2</sup>) pole and bracket cable is used in all installations regardless of the size of the conductor cable. To check the preceding result, use the basic formula: |
Voltage Drop = Current x Resistance | Voltage Drop = Current x Resistance | ||
− | To determine the current in amperes, use length of wires (2 x distance) x number of | + | To determine the current in amperes, use length of wires (2 x distance) x number of luminaires x line amperes. [[902.15_Designing_a_Traffic_Signal#Table_902.15.6.2.1_Properties_for_Conductors|Table 902.15.6.2.1 Properties for Conductors]] shows the resistance of #8 AWG (10 mm<sup>2</sup>) wire in ohms/1000 ft = 0.78 (ohms/1000 m = 2.2). |
Therefore: | Therefore: | ||
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ENGLISH | ENGLISH | ||
− | 2 wires x 1200 ft x 1.05 x 5 | + | 2 wires x 1200 ft x 1.05 x 5 luminaires x 0.71 x 0.78 ohms/1000 ft = 6.98 volt drop to 1st luminaire |
− | 2 wires x 500 ft x 1.05 x 4 | + | 2 wires x 500 ft x 1.05 x 4 luminaires x 0.71 x 0.78 ohms/1000 ft = 2.33 volt drop to 2nd luminaire |
− | 2 wires x 2000 ft x 1.05 x 3 | + | 2 wires x 2000 ft x 1.05 x 3 luminaires x 0.71 x 0.78 ohms/1000 ft = 6.98 volt drop to 3rd luminaire |
− | 2 wires x 600 ft x 1.05 x 2 | + | 2 wires x 600 ft x 1.05 x 2 luminaires x 0.71 x 0.78 ohms/1000 ft = 1.40 volt drop to 4th luminaire |
− | 2 wires x 300 ft x 1.05 x 1 | + | 2 wires x 300 ft x 1.05 x 1 luminaire x 0.71 x 0.78 ohms/1000 ft = 0.35 volt drop to 5th luminaire |
− | + | ::: Total Drop = 18.03 volts and 18.03 volts/(480 volts x .95) = 3.96% | |
METRIC | METRIC | ||
− | 2 wires x 350 m x 1.05 x 5 | + | 2 wires x 350 m x 1.05 x 5 luminaires x 0.71 x 2.2 ohms/1000 m = 5.74 volt drop to 1st luminaire |
− | 2 wires x 150 m x 1.05 x 4 | + | 2 wires x 150 m x 1.05 x 4 luminaires x 0.71 x 2.2 ohms/1000 m = 1.97 volt drop to 2nd luminaire |
− | 2 wires x 600 m x 1.05 x 3 | + | 2 wires x 600 m x 1.05 x 3 luminaires x 0.71 x 2.2 ohms/1000 m = 5.90 volt drop to 3rd luminaire |
− | 2 wires x 200 m x 1.05 x 2 | + | 2 wires x 200 m x 1.05 x 2 luminaires x 0.71 x 2.2 ohms/1000 m = 1.31 volt drop to 4th luminaire |
− | 2 wires x 100 m x 1.05 x 1 | + | 2 wires x 100 m x 1.05 x 1 luminaire x 0.71 x 2.2 ohms/1000 m = 0.33 volt drop to 5th luminaire |
− | + | ::: Total Drop = 15.25 volts and 15.25 volts/(480 volts x .95) = 3.34% | |
Circuit loading due to line losses is also to be calculated for the purpose of sizing circuit breakers. The formula for power, P = I x V is used. Total current on each segment and the voltage drop as calculated above is used: | Circuit loading due to line losses is also to be calculated for the purpose of sizing circuit breakers. The formula for power, P = I x V is used. Total current on each segment and the voltage drop as calculated above is used: | ||
Line 141: | Line 135: | ||
ENGLISH | ENGLISH | ||
− | 5 | + | 5 luminaires x 0.71 amps x 6.98 volts = 25 watts consumed to the 1st luminaire |
− | 4 | + | 4 luminaires x 0.71 amps x 2.33 volts = 7 watts consumed to the 2nd luminaire |
− | 3 | + | 3 luminaires x 0.71 amps x 6.98 volts = 15 watts consumed to the 3rd luminaire |
− | 2 | + | 2 luminaires x 0.71 amps x 1.40 volts = 2 watts consumed to the 4th luminaire |
− | 1 | + | 1 luminaire x 0.71 amps x 0.35 volts = 0 watts consumed to the 5th luminaire |
− | + | ::: Total line loss load = 49 watts. | |
METRIC | METRIC | ||
− | 5 | + | 5 luminaires x 0.71 amps x 5.74 volts = 21 watts consumed to the 1st luminaire |
− | 4 | + | 4 luminaires x 0.71 amps x 1.97 volts = 6 watts consumed to the 2nd luminaire |
− | 3 | + | 3 luminaires x 0.71 amps x 5.90 volts = 13 watts consumed to the 3rd luminaire |
− | 2 | + | 2 luminaires x 0.71 amps x 1.31 volts = 2 watts consumed to the 4th luminaire |
− | 1 | + | 1 luminaire x 0.71 amps x 0.33 volts = 0 watts consumed to the 5th luminaire |
− | + | ::: Total line loss load = 42 watts. | |
==901.12.2 Circuit Breakers== | ==901.12.2 Circuit Breakers== | ||
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Circuit breakers are protective devices for over-current conditions. When the current passing through the circuit breaker coils exceeds a predetermined amount, the magnetic field developed is sufficiently large in magnetomotive force to trip the contacts and open the faulty circuit. The amount of current required to operate the trip mechanism is referred to as the "trip rating". Proper protection of the circuit requires a breaker with the correct "tripping" current value. This value, "trip rating", can readily be computed by totaling the number of luminaires for each circuit breaker and thereby obtaining the total current being used in the circuit. | Circuit breakers are protective devices for over-current conditions. When the current passing through the circuit breaker coils exceeds a predetermined amount, the magnetic field developed is sufficiently large in magnetomotive force to trip the contacts and open the faulty circuit. The amount of current required to operate the trip mechanism is referred to as the "trip rating". Proper protection of the circuit requires a breaker with the correct "tripping" current value. This value, "trip rating", can readily be computed by totaling the number of luminaires for each circuit breaker and thereby obtaining the total current being used in the circuit. | ||
− | To prevent unnecessary tripping of the breaker during surges and in-rush currents, the total current is usually multiplied by a factor of 1.3. Using the previous example: 5 each - | + | To prevent unnecessary tripping of the breaker during surges and in-rush currents, the total current is usually multiplied by a factor of 1.3. Using the previous example: 5 each LED-B luminaires require a normal operating current of 5 x (0.71 ampere) = 3.67 amperes. |
The line loss load in amperes is added as follows: | The line loss load in amperes is added as follows: | ||
− | + | :: 42 watts/(480 volts x 0.95) + 3.6 amps = 3.7 amps | |
− | + | :: Then: Trip rating = 3.7 amps x (1.3) = 4.8 amps. | |
Conventional circuit breakers for lighting systems are used in the following trip ratings: 15, 20, 25, 30, 35, 40, 50, 70, 90 and 100 amperes. For the above example, a 15-amp breaker would be used. | Conventional circuit breakers for lighting systems are used in the following trip ratings: 15, 20, 25, 30, 35, 40, 50, 70, 90 and 100 amperes. For the above example, a 15-amp breaker would be used. | ||
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[[Category:901 Lighting]] | [[Category:901 Lighting]] |
Latest revision as of 07:27, 29 May 2024
901.12.1 Voltage Drop and Wire Sizes
Voltage drop is an important factor in determining wire sizes. The voltage drop in any electrical circuit is directly dependent upon current and wire resistance. According to Ohm's Law the voltage drop in a line is equal to the current in amperes multiplied by the resistance of the line in ohms:
E = I x R
Where:
E = voltage
I = Current (in amperes)
R = Resistance (in ohms)
Since the resistance of a wire conductor is inversely proportional to the cross-sectional area of the wire, increased voltage drops are developed as the wire diameters decrease.
The areas of wires in circular mils (mm2) and the resistance in ohms per 1000 ft. (1000 m) to be used in calculations are shown in 902.15.6.2 Power Cable. The voltage drop in any line is calculated from the formula:
- ENGLISH
- METRIC
Transposing this formula, the required area in circular mils (mm2) can be computed:
- ENGLISH
- METRIC
With the constant wattage ballast, the permissible voltage drop is five percent of the system voltage. A factor of 0.95 is to be applied to the system voltage to allow for line fluctuations. This results in an allowable drop of 23 volts for a 480-volt circuit, and 11 volts for a 240-volt circuit.
901.12.1.1 Maximum Wire Sizes. Maximum wire sizes for lighting branch circuits (cables between control station and light poles) are as follows:
- Standard Light Poles (30 and 45 ft. mounting height) and Underpass Luminaires - #6 AWG (16 mm2) MAXIMUM
- High Mast Light Poles - #2 AWG (35 mm2) MAXIMUM
If circuit loading or voltage drop requires a larger wire size than the maximum, then one or more of the following can be considered:
- Increase the system voltage from 240 volts to 480 volts.
- Split the circuits into additional branch circuits. This may require parallel cable conduits in some parts of the system.
- Locate the control station closer to the lighting system.
- Install additional control stations.
Availability and proximity of power sources and system voltages is considered in obtaining the best solution. Where alternate configurations can achieve the same results, a rough cost comparison is made to determine the most economical configuration.
Wire sizes larger than #0 AWG (70 mm2) are not recommended for power supply cables (cables between power supply and base-mounted control station) since larger wire sizes are difficult to handle in the control stations and power supplies. If a larger wire size is required, a terminal strip is provided in the control cabinet to reduce the wire size.
901.12.1.2 Example to Determine Necessary Wire Cable Size
Given: Five LED-B luminaires on a 480-volt circuit at 1200, 1700, 3700, 4300 and 4600 ft. (350, 500, 1100, 1300 and 1400 m), respectively, from the control station.
There must be sufficient current to operate the first luminaries as well as the next four luminaires, etc. Operating current is obtained from the manufacturer of the luminaire. For our example we will assume 0.71 amps.
It is also necessary to add 5% to the wire length to allow for snaking.
ENGLISH
1200 ft x 1.05 x 5 luminaires x 0.71 amps x 25/23 (Permissible Drop) = 4862 cir. mils to 1st luminaire
500 ft x 1.05 x 4 luminaires x 0.71 x 25/23 = 1621 cir. mils to 2nd luminaire
2000 ft x 1.05 x 3 luminaires x 0.71 x 25/23 = 4862 cir. mils to 3rd luminaire
600 ft x 1.05 x 2 luminaires x 0.71 x 25/23 = 972 cir. mils to 4th luminaire
300 ft x 1.05 x 1 luminaire x 0.71 x 25/23 = 243 cir. mils to 5th luminaire
- Total Area = 12,560 cir. mils.
METRIC
350 m x 1.05 x 5 luminaires x 0.71 amps x 0.04125/23 (Permissible Drop) = 2.34 mm2 to 1st luminaire
150 m x 1.05 x 4 luminaires x 0.71 x 0.04125/23 = 0.80 mm2 to 2nd luminaire
600 m x 1.05 x 3 luminaires x 0.71 x 0.04125/23 = 2.41 mm2 to 3rd luminaire
200 m x 1.05 x 2 luminaires x 0.71 x 0.04125/23 = 0.54 mm2 to 4th luminaire
100 m x 1.05 x 1 luminaires x 0.71 x 0.04125/23 = 0.13 mm2 to 5th luminaire
- Total Area = 6.22 mm2.
The wire size is that with the area next above, as shown in Table 902.15.6.2.1 Properties for Conductors or #8 AWG (10 mm2) (The minimum size used in cable-conduit is #8 AWG (10 mm2)). When several circuits are carried from one control station, determine the wire size for each circuit separately. #10 AWG (6 mm2) pole and bracket cable is used in all installations regardless of the size of the conductor cable. To check the preceding result, use the basic formula:
Voltage Drop = Current x Resistance
To determine the current in amperes, use length of wires (2 x distance) x number of luminaires x line amperes. Table 902.15.6.2.1 Properties for Conductors shows the resistance of #8 AWG (10 mm2) wire in ohms/1000 ft = 0.78 (ohms/1000 m = 2.2).
Therefore:
ENGLISH
2 wires x 1200 ft x 1.05 x 5 luminaires x 0.71 x 0.78 ohms/1000 ft = 6.98 volt drop to 1st luminaire
2 wires x 500 ft x 1.05 x 4 luminaires x 0.71 x 0.78 ohms/1000 ft = 2.33 volt drop to 2nd luminaire
2 wires x 2000 ft x 1.05 x 3 luminaires x 0.71 x 0.78 ohms/1000 ft = 6.98 volt drop to 3rd luminaire
2 wires x 600 ft x 1.05 x 2 luminaires x 0.71 x 0.78 ohms/1000 ft = 1.40 volt drop to 4th luminaire
2 wires x 300 ft x 1.05 x 1 luminaire x 0.71 x 0.78 ohms/1000 ft = 0.35 volt drop to 5th luminaire
- Total Drop = 18.03 volts and 18.03 volts/(480 volts x .95) = 3.96%
METRIC
2 wires x 350 m x 1.05 x 5 luminaires x 0.71 x 2.2 ohms/1000 m = 5.74 volt drop to 1st luminaire
2 wires x 150 m x 1.05 x 4 luminaires x 0.71 x 2.2 ohms/1000 m = 1.97 volt drop to 2nd luminaire
2 wires x 600 m x 1.05 x 3 luminaires x 0.71 x 2.2 ohms/1000 m = 5.90 volt drop to 3rd luminaire
2 wires x 200 m x 1.05 x 2 luminaires x 0.71 x 2.2 ohms/1000 m = 1.31 volt drop to 4th luminaire
2 wires x 100 m x 1.05 x 1 luminaire x 0.71 x 2.2 ohms/1000 m = 0.33 volt drop to 5th luminaire
- Total Drop = 15.25 volts and 15.25 volts/(480 volts x .95) = 3.34%
Circuit loading due to line losses is also to be calculated for the purpose of sizing circuit breakers. The formula for power, P = I x V is used. Total current on each segment and the voltage drop as calculated above is used:
ENGLISH
5 luminaires x 0.71 amps x 6.98 volts = 25 watts consumed to the 1st luminaire
4 luminaires x 0.71 amps x 2.33 volts = 7 watts consumed to the 2nd luminaire
3 luminaires x 0.71 amps x 6.98 volts = 15 watts consumed to the 3rd luminaire
2 luminaires x 0.71 amps x 1.40 volts = 2 watts consumed to the 4th luminaire
1 luminaire x 0.71 amps x 0.35 volts = 0 watts consumed to the 5th luminaire
- Total line loss load = 49 watts.
METRIC
5 luminaires x 0.71 amps x 5.74 volts = 21 watts consumed to the 1st luminaire
4 luminaires x 0.71 amps x 1.97 volts = 6 watts consumed to the 2nd luminaire
3 luminaires x 0.71 amps x 5.90 volts = 13 watts consumed to the 3rd luminaire
2 luminaires x 0.71 amps x 1.31 volts = 2 watts consumed to the 4th luminaire
1 luminaire x 0.71 amps x 0.33 volts = 0 watts consumed to the 5th luminaire
- Total line loss load = 42 watts.
901.12.2 Circuit Breakers
Circuit breakers are protective devices for over-current conditions. When the current passing through the circuit breaker coils exceeds a predetermined amount, the magnetic field developed is sufficiently large in magnetomotive force to trip the contacts and open the faulty circuit. The amount of current required to operate the trip mechanism is referred to as the "trip rating". Proper protection of the circuit requires a breaker with the correct "tripping" current value. This value, "trip rating", can readily be computed by totaling the number of luminaires for each circuit breaker and thereby obtaining the total current being used in the circuit.
To prevent unnecessary tripping of the breaker during surges and in-rush currents, the total current is usually multiplied by a factor of 1.3. Using the previous example: 5 each LED-B luminaires require a normal operating current of 5 x (0.71 ampere) = 3.67 amperes.
The line loss load in amperes is added as follows:
- 42 watts/(480 volts x 0.95) + 3.6 amps = 3.7 amps
- Then: Trip rating = 3.7 amps x (1.3) = 4.8 amps.
Conventional circuit breakers for lighting systems are used in the following trip ratings: 15, 20, 25, 30, 35, 40, 50, 70, 90 and 100 amperes. For the above example, a 15-amp breaker would be used.