Explanation:
When the leads of the voltmeter are placed at T3 and T4, the meter will indicate 120 volts. This is because T3 and T4 represent the hot legs of a split-phase 240-volt system, and measuring between them gives the voltage across one phase, which is typically 120 volts in a residential electrical system.
Explanation:
When calculating residential service load, 1,500 volt-amperes are allowed for each branch circuit serving laundry receptacles. This allowance accounts for the typical load of laundry appliances such as washing machines and dryers, ensuring that the electrical system is adequately sized to handle the expected demand.
Explanation:
In a multi-wire branch circuit, the neutral current is calculated by summing the unbalanced currents of the circuits sharing the neutral. In this case, circuit 7 is drawing 13 amps, and circuit 9 will draw 16 amps. Therefore, the unbalanced current is 3 amps (16 amps - 13 amps). So, 3 amps is flowing in the neutral.
Explanation:
An extension ladder should extend 3 feet above the top of the building and be secured. This extension provides stability and ensures safe access to and from the roof or elevated area.
Explanation:
The minimum number of receptacles required in an unfinished basement is 1. This receptacle is typically installed within 6 feet of the stairs, and additional receptacles are recommended at regular intervals along the walls to ensure adequate access to power throughout the space.
Explanation:
To minimize conductor insulation damage and arcing damage to electrical equipment during a ground fault or a short circuit, the time duration of the fault should be minimized. Shortening the duration reduces the amount of heat generated and the potential for damage, helping to protect both the conductors and the electrical equipment connected to them.
Explanation:
A service lateral typically refers to the underground feed that connects the utility service to a building's electrical distribution system. It's an underground conduit or cable that delivers electrical power from the utility's distribution system to the service entrance of a building.
Explanation:
To calculate the kWh (kilowatt-hours) consumed by the lamp, multiply the wattage of the lamp by the hours it operates:
60 watts × 21 hours = 1260 watt-hours
Then, convert watt-hours to kilowatt-hours by dividing by 1000:
1260 watt-hours ÷ 1000 = 1.260 kWh
So, the utility will bill for 1.260 kWh.
Explanation:
To calculate the monthly energy cost, first, determine the energy consumption per day:
Energy consumption per day = Power of lamp (in kW) × Hours of operation per day
Energy consumption per day = (250 W / 1000) kW × 8 hours = 2 kWh
Then, calculate the total energy consumption for the month:
Total energy consumption for the month = Energy consumption per day × Days in a billing month
Total energy consumption for the month = 2 kWh/day × 30 days = 60 kWh
Finally, determine the total cost:
Total cost = Total energy consumption × Cost per kWh
Total cost = 60 kWh × $0.15/kWh = $9.00
Explanation:
The Standard for Electrical Safety in the Workplace requires that all electrical equipment operating at over 50 volts to ground be de-energized and locked out before anyone is permitted to work on or near the equipment. This ensures the safety of workers by preventing accidental contact with live electrical components.
Explanation:
For a 125-amp, 120/240-V, 3W residential service, 2 AWG copper THHN/THWN conductors are the smallest permitted for the underground conductors. This gauge ensures that the conductors can safely carry the current without overheating or exceeding voltage drop limits over the distance of the underground run.